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gnu / binutils-gdb / ecfc6ddb8074aff8882155b5900958725094f508 / . / sim / ppc / ppc-instructions
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#
# This file is part of the program psim.
#
# Copyright 1994, 1995, 1996, 1997, 2003, 2004 Andrew Cagney
#
# --
#
# The pseudo-code that appears below, translated into C, was copied
# by Andrew Cagney of Moss Vale, Australia.
#
# This pseudo-code is copied by permission from the publication
# "The PowerPC Architecture: A Specification for A New Family of
# RISC Processors" (ISBN 1-55860-316-6) copyright 1993, 1994 by
# International Business Machines Corporation.
#
# THIS PERMISSION IS PROVIDED WITHOUT WARRANTY OF ANY KIND, EITHER
# EXPRESSED OR IMPLIED, INCLUDING BUT NOT LIMITED TO IMPLIED WARRANTIES
# OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
#
# --
#
# 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/>.
#
:cache::::RA:RA:
:cache:::signed_word *:rA:RA:(cpu_registers(processor)->gpr + RA)
:cache:::uint32_t:RA_BITMASK:RA:(1 << RA)
:compute:::int:RA_is_0:RA:(RA == 0)
:cache::::RT:RT:
:cache:::signed_word *:rT:RT:(cpu_registers(processor)->gpr + RT)
:cache:::uint32_t:RT_BITMASK:RT:(1 << RT)
:cache::::RS:RS:
:cache:::signed_word *:rS:RS:(cpu_registers(processor)->gpr + RS)
:cache:::uint32_t:RS_BITMASK:RS:(1 << RS)
:cache::::RB:RB:
:cache:::signed_word *:rB:RB:(cpu_registers(processor)->gpr + RB)
:cache:::uint32_t:RB_BITMASK:RB:(1 << RB)
:scratch::::FRA:FRA:
:cache:::uint64_t *:frA:FRA:(cpu_registers(processor)->fpr + FRA)
:cache:::uint32_t:FRA_BITMASK:FRA:(1 << FRA)
:scratch::::FRB:FRB:
:cache:::uint64_t *:frB:FRB:(cpu_registers(processor)->fpr + FRB)
:cache:::uint32_t:FRB_BITMASK:FRB:(1 << FRB)
:scratch::::FRC:FRC:
:cache:::uint64_t *:frC:FRC:(cpu_registers(processor)->fpr + FRC)
:cache:::uint32_t:FRC_BITMASK:FRC:(1 << FRC)
:scratch::::FRS:FRS:
:cache:::uint64_t *:frS:FRS:(cpu_registers(processor)->fpr + FRS)
:cache:::uint32_t:FRS_BITMASK:FRS:(1 << FRS)
:scratch::::FRT:FRT:
:cache:::uint64_t *:frT:FRT:(cpu_registers(processor)->fpr + FRT)
:cache:::uint32_t:FRT_BITMASK:FRT:(1 << FRT)
:cache:::unsigned_word:EXTS_SI:SI:((signed_word)(int16_t)instruction)
:scratch::::BI:BI:
:cache::::BIT32_BI:BI:BIT32(BI)
:cache::::BF:BF:
:cache:::uint32_t:BF_BITMASK:BF:(1 << BF)
:scratch::::BA:BA:
:cache::::BIT32_BA:BA:BIT32(BA)
:cache:::uint32_t:BA_BITMASK:BA:(1 << BA)
:scratch::::BB:BB:
:cache::::BIT32_BB:BB:BIT32(BB)
:cache:::uint32_t:BB_BITMASK:BB:(1 << BB)
:cache::::BT:BT:
:cache:::uint32_t:BT_BITMASK:BT:(1 << BT)
:cache:::unsigned_word:EXTS_BD_0b00:BD:(((signed_word)(int16_t)instruction) & ~3)
:cache:::unsigned_word:EXTS_LI_0b00:LI:((((signed_word)(int32_t)(instruction << 6)) >> 6) & ~0x3)
:cache:::unsigned_word:EXTS_D:D:((signed_word)(int16_t)(instruction))
:cache:::unsigned_word:EXTS_DS_0b00:DS:(((signed_word)(int16_t)instruction) & ~0x3)
#:compute:::int:SPR_is_256:SPR:(SPR == 256)
# PowerPC models
::model:604:ppc604: PPC_UNIT_BAD, PPC_UNIT_BAD, 1, 1, 0
::model:603e:ppc603e:PPC_UNIT_BAD, PPC_UNIT_BAD, 1, 1, 0
::model:603:ppc603: PPC_UNIT_BAD, PPC_UNIT_BAD, 1, 1, 0
::model:601:ppc601: PPC_UNIT_BAD, PPC_UNIT_BAD, 1, 1, 0
# Flags for model.h
::model-macro:::
#define PPC_INSN_INT(OUT_MASK, IN_MASK, RC) \
do { \
if (CURRENT_MODEL_ISSUE > 0) { \
if (RC) \
ppc_insn_int_cr(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK, 1 << 0); \
else \
ppc_insn_int(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK); \
} \
} while (0)
#define PPC_INSN_INT_CR(OUT_MASK, IN_MASK, CR_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_int_cr(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK, CR_MASK); \
} while (0)
#define PPC_INSN_CR(OUT_MASK, IN_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_cr(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK); \
} while (0)
#define PPC_INSN_FLOAT(OUT_MASK, IN_MASK, RC) \
do { \
if (CURRENT_MODEL_ISSUE > 0) { \
if (RC) \
ppc_insn_float(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK); \
else \
ppc_insn_float_cr(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK, 1 << 0); \
} \
} while (0)
#define PPC_INSN_FLOAT_CR(OUT_MASK, IN_MASK, CR_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_float_cr(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK, CR_MASK); \
} while (0)
#define PPC_INSN_INT_FLOAT(OUT_INT_MASK, OUT_FP_MASK, IN_INT_MASK, IN_FP_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_int_float(MY_INDEX, cpu_model(processor), OUT_INT_MASK, OUT_FP_MASK, IN_INT_MASK, IN_FP_MASK); \
} while (0)
#define PPC_INSN_FROM_SPR(INT_MASK, SPR) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_from_spr(MY_INDEX, cpu_model(processor), INT_MASK, SPR); \
} while (0)
#define PPC_INSN_TO_SPR(INT_MASK, SPR) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_to_spr(MY_INDEX, cpu_model(processor), INT_MASK, SPR); \
} while (0)
#define PPC_INSN_MFCR(INT_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_mfcr(MY_INDEX, cpu_model(processor), INT_MASK); \
} while (0)
#define PPC_INSN_MTCR(INT_MASK, FXM) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_mtcr(MY_INDEX, cpu_model(processor), INT_MASK, FXM); \
} while (0)
::model-data:::
typedef enum _ppc_function_unit {
PPC_UNIT_BAD, /* unknown function unit */
PPC_UNIT_IU, /* integer unit (601/603 style) */
PPC_UNIT_SRU, /* system register unit (601/603 style) */
PPC_UNIT_SCIU1, /* 1st single cycle integer unit (604 style) */
PPC_UNIT_SCIU2, /* 2nd single cycle integer unit (604 style) */
PPC_UNIT_MCIU, /* multiple cycle integer unit (604 style) */
PPC_UNIT_FPU, /* floating point unit */
PPC_UNIT_LSU, /* load/store unit */
PPC_UNIT_BPU, /* branch unit */
nr_ppc_function_units
} ppc_function_unit;
/* Structure to hold timing information on a per instruction basis */
struct _model_time {
ppc_function_unit first_unit; /* first functional unit this insn could use */
ppc_function_unit second_unit; /* second functional unit this insn could use */
int16_t issue; /* # cycles before function unit can process other insns */
int16_t done; /* # cycles before insn is done */
uint32_t flags; /* any flags that are needed */
};
/* Register mappings in status masks */
#define PPC_CR_REG 0 /* start of CR0 .. CR7 */
#define PPC_FPSCR_REG (PPC_CR_REG + 8) /* start of fpscr register */
#define PPC_NO_SPR (-1) /* flag for no SPR register */
/* Return if 1 bit set */
#define PPC_ONE_BIT_SET_P(x) (((x) & ((x)-1)) == 0)
/* Structure for each functional unit that is busy */
typedef struct _model_busy model_busy;
struct _model_busy {
model_busy *next; /* next function unit */
ppc_function_unit unit; /* function unit name */
uint32_t int_busy; /* int registers that are busy */
uint32_t fp_busy; /* floating point registers that are busy */
uint32_t cr_fpscr_busy; /* CR/FPSCR registers that are busy */
int16_t spr_busy; /* SPR register that is busy or PPC_NO_SPR */
uint32_t vr_busy; /* AltiVec registers that are busy */
int16_t vscr_busy; /* AltiVec status register busy */
int16_t issue; /* # of cycles until unit can accept another insn */
int16_t done; /* # of cycles until insn is done */
int16_t nr_writebacks; /* # of registers this unit writes back */
};
/* Structure to hold the current state information for the simulated CPU model */
struct _model_data {
cpu *processor; /* point back to processor */
const char *name; /* model name */
const model_time *timing; /* timing information */
model_busy busy_head; /* dummy entry to head list of busy function units */
model_busy *busy_tail; /* tail of list of busy function units */
model_busy *free_list; /* list of model_busy structs not in use */
count_type nr_cycles; /* # cycles */
count_type nr_branches; /* # branches */
count_type nr_branches_fallthrough; /* # conditional branches that fell through */
count_type nr_branch_predict_trues; /* # branches predicted correctly */
count_type nr_branch_predict_falses; /* # branches predicted incorrectly */
count_type nr_branch_conditional[32]; /* # of each type of bc */
count_type nr_mtcrf_crs[9]; /* # of CR's moved in a mtcrf instruction */
count_type nr_stalls_data; /* # of stalls for data */
count_type nr_stalls_unit; /* # of stalls waiting for a function unit */
count_type nr_stalls_serialize; /* # of stalls waiting for things to quiet down */
count_type nr_stalls_writeback; /* # of stalls waiting for a writeback slot */
count_type nr_units[nr_ppc_function_units]; /* function unit counts */
int max_nr_writebacks; /* max # of writeback slots available */
uint32_t int_busy; /* int registers that are busy */
uint32_t fp_busy; /* floating point registers that are busy */
uint32_t cr_fpscr_busy; /* CR/FPSCR registers that are busy */
uint8_t spr_busy[nr_of_sprs]; /* SPR registers that are busy */
uint32_t vr_busy; /* AltiVec registers that are busy */
uint8_t vscr_busy; /* AltiVec SC register busy */
uint8_t busy[nr_ppc_function_units]; /* whether a function is busy or not */
};
static const char *const ppc_function_unit_name[ (int)nr_ppc_function_units ] = {
"unknown functional unit instruction",
"integer functional unit instruction",
"system register functional unit instruction",
"1st single cycle integer functional unit instruction",
"2nd single cycle integer functional unit instruction",
"multiple cycle integer functional unit instruction",
"floating point functional unit instruction",
"load/store functional unit instruction",
"branch functional unit instruction",
};
static const char *const ppc_branch_conditional_name[32] = {
"branch if --CTR != 0 and condition is FALSE", /* 0000y */
"branch if --CTR != 0 and condition is FALSE, reverse branch likely",
"branch if --CTR == 0 and condition is FALSE", /* 0001y */
"branch if --CTR == 0 and condition is FALSE, reverse branch likely",
"branch if the condition is FALSE", /* 001zy */
"branch if the condition is FALSE, reverse branch likely",
"branch if the condition is FALSE (ignored bit 1 set to 1)", /* 001zy */
"branch if the condition is FALSE, reverse branch likely (ignored bit 4 set to 1)",
"branch if --CTR != 0 and condition is TRUE", /* 0100y */
"branch if --CTR != 0 and condition is TRUE, reverse branch likely",
"branch if --CTR == 0 and condition is TRUE", /* 0101y */
"branch if --CTR == 0 and condition is TRUE, reverse branch likely",
"branch if the condition is TRUE", /* 011zy */
"branch if the condition is TRUE, reverse branch likely",
"branch if the condition is TRUE (ignored bit 1 set to 1)", /* 011zy */
"branch if the condition is TRUE, reverse branch likely (ignored bit 4 set to 1)",
"branch if --CTR != 0", /* 1z00y */
"branch if --CTR != 0, reverse branch likely",
"branch if --CTR == 0", /* 1z01y */
"branch if --CTR == 0, reverse branch likely",
"branch always", /* 1z1zz */
"branch always (ignored bit 5 set to 1)",
"branch always (ignored bit 4 set to 1)", /* 1z1zz */
"branch always (ignored bits 4,5 set to 1)",
"branch if --CTR != 0 (ignored bit 1 set to 1)", /* 1z00y */
"branch if --CTR != 0, reverse branch likely (ignored bit 1 set to 1)",
"branch if --CTR == 0 (ignored bit 1 set to 1)", /* 1z01y */
"branch if --CTR == 0, reverse branch likely (ignored bit 1 set to 1)",
"branch always (ignored bit 1 set to 1)", /* 1z1zz */
"branch always (ignored bits 1,5 set to 1)",
"branch always (ignored bits 1,4 set to 1)", /* 1z1zz */
"branch always (ignored bits 1,4,5 set to 1)",
};
static const char *const ppc_nr_mtcrf_crs[9] = {
"mtcrf moving 0 CRs",
"mtcrf moving 1 CR",
"mtcrf moving 2 CRs",
"mtcrf moving 3 CRs",
"mtcrf moving 4 CRs",
"mtcrf moving 5 CRs",
"mtcrf moving 6 CRs",
"mtcrf moving 7 CRs",
"mtcrf moving all CRs",
};
# Trace releasing resources
void::model-static::model_trace_release:model_data *model_ptr, model_busy *busy
int i;
TRACE(trace_model,("done, %s, %d writeback%s\n", ppc_function_unit_name[busy->unit],
busy->nr_writebacks, busy->nr_writebacks == 1 ? "" : "s"));
if (busy->int_busy) {
for(i = 0; i < 32; i++) {
if (((1 << i) & busy->int_busy) != 0) {
TRACE(trace_model, ("Register r%d is now available.\n", i));
}
}
}
if (busy->fp_busy) {
for(i = 0; i < 32; i++) {
if (((1 << i) & busy->fp_busy) != 0) {
TRACE(trace_model, ("Register f%d is now available.\n", i));
}
}
}
if (busy->cr_fpscr_busy) {
for(i = 0; i < 8; i++) {
if (((1 << i) & busy->cr_fpscr_busy) != 0) {
TRACE(trace_model, ("Register cr%d is now available.\n", i));
}
}
if (busy->cr_fpscr_busy & 0x100)
TRACE(trace_model, ("Register fpscr is now available.\n"));
}
if (busy->spr_busy != PPC_NO_SPR)
TRACE(trace_model, ("Register %s is now available.\n", spr_name(busy->spr_busy)));
if (busy->vr_busy) {
for(i = 0; i < 32; i++) {
if (((1 << i) & busy->vr_busy) != 0) {
TRACE(trace_model, ("Register v%d is now available.\n", i));
}
}
}
if (busy->vscr_busy)
TRACE(trace_model, ("VSCR Register %s is now available.\n", spr_name(busy->spr_busy)));
# Trace making registers busy
void::model-static::model_trace_make_busy:model_data *model_ptr, uint32_t int_mask, uint32_t fp_mask, uint32_t cr_mask
int i;
if (int_mask) {
for(i = 0; i < 32; i++) {
if (((1 << i) & int_mask) != 0) {
TRACE(trace_model, ("Register r%d is now busy.\n", i));
}
}
}
if (fp_mask) {
for(i = 0; i < 32; i++) {
if (((1 << i) & fp_mask) != 0) {
TRACE(trace_model, ("Register f%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));
}
}
}
# Trace waiting for registers to become available
void::model-static::model_trace_busy_p:model_data *model_ptr, uint32_t int_busy, uint32_t fp_busy, uint32_t cr_or_fpscr_busy, int spr_busy
int i;
if (int_busy) {
int_busy &= model_ptr->int_busy;
for(i = 0; i < 32; i++) {
if (((1 << i) & int_busy) != 0) {
TRACE(trace_model, ("Waiting for register r%d.\n", i));
}
}
}
if (fp_busy) {
fp_busy &= model_ptr->fp_busy;
for(i = 0; i < 32; i++) {
if (((1 << i) & fp_busy) != 0) {
TRACE(trace_model, ("Waiting for register f%d.\n", i));
}
}
}
if (cr_or_fpscr_busy) {
cr_or_fpscr_busy &= model_ptr->cr_fpscr_busy;
for(i = 0; i < 8; i++) {
if (((1 << i) & cr_or_fpscr_busy) != 0) {
TRACE(trace_model, ("Waiting for register cr%d.\n", i));
}
}
if (cr_or_fpscr_busy & 0x100)
TRACE(trace_model, ("Waiting for register fpscr.\n"));
}
if (spr_busy != PPC_NO_SPR && model_ptr->spr_busy[spr_busy])
TRACE(trace_model, ("Waiting for register %s.\n", spr_name(spr_busy)));
# Advance state to next cycle, releasing any registers allocated
void::model-internal::model_new_cycle:model_data *model_ptr
model_busy *cur_busy = model_ptr->busy_head.next;
model_busy *free_list = model_ptr->free_list;
model_busy *busy_tail = &model_ptr->busy_head;
int nr_writebacks = model_ptr->max_nr_writebacks;
model_busy *next;
model_ptr->nr_cycles++;
TRACE(trace_model,("New cycle %lu\n", (unsigned long)model_ptr->nr_cycles));
for ( ; cur_busy; cur_busy = next) {
next = cur_busy->next;
if (--cur_busy->done <= 0) { /* function unit done, release registers if we have writeback slots */
nr_writebacks -= cur_busy->nr_writebacks;
if (nr_writebacks >= 0) {
model_ptr->int_busy &= ~cur_busy->int_busy;
model_ptr->fp_busy &= ~cur_busy->fp_busy;
model_ptr->cr_fpscr_busy &= ~cur_busy->cr_fpscr_busy;
if (cur_busy->spr_busy != PPC_NO_SPR)
model_ptr->spr_busy[cur_busy->spr_busy] = 0;
model_ptr->vr_busy &= ~cur_busy->vr_busy;
model_ptr->vscr_busy = ~cur_busy->vscr_busy;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_release(model_ptr, cur_busy);
model_ptr->busy[cur_busy->unit] = 0;
cur_busy->next = free_list;
free_list = cur_busy;
}
else { /* writeback slots not available */
TRACE(trace_model,("%d writeback slot%s not available for %s\n",
cur_busy->nr_writebacks,
cur_busy->nr_writebacks == 1 ? " is" : "s are",
ppc_function_unit_name[cur_busy->unit]));
cur_busy->done++; /* undo -- above */
model_ptr->nr_stalls_writeback++;
busy_tail->next = cur_busy;
busy_tail = cur_busy;
}
}
else if (--cur_busy->issue <= 0) { /* function unit pipelined, allow new use */
TRACE(trace_model,("pipeline, %s ready for next client\n", ppc_function_unit_name[cur_busy->unit]));
model_ptr->busy[cur_busy->unit] = 0;
busy_tail->next = cur_busy;
busy_tail = cur_busy;
}
else {
TRACE(trace_model,("%s still working, issue = %d, done = %d\n",
ppc_function_unit_name[cur_busy->unit],
cur_busy->issue,
cur_busy->done));
busy_tail->next = cur_busy;
busy_tail = cur_busy;
}
}
busy_tail->next = (model_busy *)0;
model_ptr->busy_tail = busy_tail;
model_ptr->free_list = free_list;
# Mark a function unit as busy, return the busy structure
model_busy *::model-internal::model_make_busy:model_data *model_ptr, ppc_function_unit unit, int issue, int done
model_busy *busy;
TRACE(trace_model,("unit = %s, issue = %d, done = %d\n", ppc_function_unit_name[unit], issue, done));
if (!model_ptr->free_list) {
busy = ZALLOC(model_busy);
}
else {
busy = model_ptr->free_list;
model_ptr->free_list = busy->next;
busy->next = (model_busy *)0;
busy->int_busy = 0;
busy->fp_busy = 0;
busy->cr_fpscr_busy = 0;
busy->nr_writebacks = 0;
busy->vr_busy = 0;
busy->vscr_busy = 0;
}
busy->unit = unit;
busy->issue = issue;
busy->done = done;
busy->spr_busy = PPC_NO_SPR;
model_ptr->busy_tail->next = busy;
model_ptr->busy_tail = busy;
model_ptr->busy[unit] = 1;
model_ptr->nr_units[unit]++;
return busy;
# Wait until a function unit is non-busy, and then allocate a busy pointer & return the pointer
model_busy *::model-internal::model_wait_for_unit:itable_index index, model_data *const model_ptr, const model_time *const time_ptr
ppc_function_unit first_unit = time_ptr->first_unit;
ppc_function_unit second_unit = time_ptr->second_unit;
int stall_increment = 0;
for (;;) {
if (!model_ptr->busy[first_unit])
return model_make_busy(model_ptr, first_unit,
model_ptr->timing[index].issue,
model_ptr->timing[index].done);
if (!model_ptr->busy[second_unit])
return model_make_busy(model_ptr, second_unit,
model_ptr->timing[index].issue,
model_ptr->timing[index].done);
TRACE(trace_model,("all function units are busy for %s\n", itable[index].name));
model_ptr->nr_stalls_unit += stall_increment; /* don't count first stall */
stall_increment = 1;
model_new_cycle(model_ptr);
}
# Serialize the processor, waiting for all instructions to drain out before adding an instruction.
void::model-function::model_serialize:itable_index index, model_data *model_ptr
while (model_ptr->busy_head.next) {
TRACE(trace_model,("waiting for pipeline to empty\n"));
model_ptr->nr_stalls_serialize++;
model_new_cycle(model_ptr);
}
(void) model_make_busy(model_ptr,
model_ptr->timing[index].first_unit,
model_ptr->timing[index].issue,
model_ptr->timing[index].done);
# Wait for a CR to become unbusy
void::model-function::model_wait_for_cr:model_data *model_ptr, unsigned CRBIT
unsigned u;
uint32_t cr_mask;
int cr_var = 0;
for (u = 0xc0000000; (u != 0) && (CRBIT & u) == 0; u >>= 4 )
cr_var++;
cr_mask = (1 << cr_var);
while ((model_ptr->cr_fpscr_busy & cr_mask) != 0) {
TRACE(trace_model,("waiting for CR %d\n", cr_var));
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
# Schedule an instruction that takes integer input registers and produces output registers
void::model-function::ppc_insn_int:itable_index index, model_data *model_ptr, const uint32_t out_mask, const uint32_t in_mask
const uint32_t int_mask = out_mask | in_mask;
model_busy *busy_ptr;
if ((model_ptr->int_busy & int_mask) != 0) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->int_busy & int_mask) != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, 0, 0, PPC_NO_SPR);
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;
if (out_mask)
busy_ptr->nr_writebacks = (PPC_ONE_BIT_SET_P(out_mask)) ? 1 : 2;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, out_mask, 0, 0);
# Schedule an instruction that takes integer input registers and produces output registers & sets a CR register
void::model-function::ppc_insn_int_cr:itable_index index, model_data *model_ptr, const uint32_t out_mask, const uint32_t in_mask, const uint32_t cr_mask
const uint32_t int_mask = out_mask | in_mask;
model_busy *busy_ptr;
if ((model_ptr->int_busy & int_mask) || (model_ptr->cr_fpscr_busy & cr_mask)) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->int_busy & int_mask) || (model_ptr->cr_fpscr_busy & cr_mask)) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, 0, cr_mask, PPC_NO_SPR);
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->cr_fpscr_busy |= cr_mask;
busy_ptr->cr_fpscr_busy |= cr_mask;
if (out_mask)
busy_ptr->nr_writebacks = (PPC_ONE_BIT_SET_P(out_mask)) ? 1 : 2;
if (cr_mask)
busy_ptr->nr_writebacks++;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, out_mask, 0, cr_mask);
# Schedule an instruction that takes CR input registers and produces output CR registers
void::model-function::ppc_insn_cr:itable_index index, model_data *model_ptr, const uint32_t out_mask, const uint32_t in_mask
const uint32_t cr_mask = out_mask | in_mask;
model_busy *busy_ptr;
if ((model_ptr->cr_fpscr_busy & cr_mask) != 0) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->cr_fpscr_busy & cr_mask) != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, 0, 0, cr_mask, PPC_NO_SPR);
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 |= out_mask;
busy_ptr->cr_fpscr_busy |= out_mask;
if (out_mask)
busy_ptr->nr_writebacks = 1;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, 0, 0, out_mask);
# Schedule an instruction that takes floating point input registers and produces an output fp register
void::model-function::ppc_insn_float:itable_index index, model_data *model_ptr, const uint32_t out_mask, const uint32_t in_mask
const uint32_t fp_mask = out_mask | in_mask;
model_busy *busy_ptr;
if ((model_ptr->fp_busy & fp_mask) != 0) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->fp_busy & fp_mask) != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, 0, fp_mask, 0, PPC_NO_SPR);
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->fp_busy |= out_mask;
busy_ptr->fp_busy |= out_mask;
busy_ptr->nr_writebacks = 1;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, 0, out_mask, 0);
# Schedule an instruction that takes floating point input registers and produces an output fp register & sets a CR reg
void::model-function::ppc_insn_float_cr:itable_index index, model_data *model_ptr, const uint32_t out_mask, const uint32_t in_mask, const uint32_t cr_mask
const uint32_t fp_mask = out_mask | in_mask;
model_busy *busy_ptr;
if ((model_ptr->fp_busy & fp_mask) || (model_ptr->cr_fpscr_busy & cr_mask)) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->fp_busy & fp_mask) || (model_ptr->cr_fpscr_busy & cr_mask)) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, 0, fp_mask, cr_mask, PPC_NO_SPR);
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->fp_busy |= out_mask;
busy_ptr->fp_busy |= out_mask;
model_ptr->cr_fpscr_busy |= cr_mask;
busy_ptr->cr_fpscr_busy |= cr_mask;
busy_ptr->nr_writebacks = (cr_mask) ? 2 : 1;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, 0, out_mask, cr_mask);
# Schedule an instruction that takes both int/float input registers and produces output int/float registers
void::model-function::ppc_insn_int_float:itable_index index, model_data *model_ptr, const uint32_t out_int_mask, const uint32_t out_fp_mask, const uint32_t in_int_mask, const uint32_t in_fp_mask
const uint32_t int_mask = out_int_mask | in_int_mask;
const uint32_t fp_mask = out_fp_mask | in_fp_mask;
model_busy *busy_ptr;
if ((model_ptr->int_busy & int_mask) || (model_ptr->fp_busy & fp_mask)) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->int_busy & int_mask) || (model_ptr->fp_busy & fp_mask)) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, fp_mask, 0, PPC_NO_SPR);
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_int_mask;
busy_ptr->int_busy |= out_int_mask;
model_ptr->fp_busy |= out_fp_mask;
busy_ptr->fp_busy |= out_fp_mask;
busy_ptr->nr_writebacks = ((out_int_mask) ? 1 : 0) + ((out_fp_mask) ? 1 : 0);
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, out_int_mask, out_fp_mask, 0);
return;
}
# Schedule an MFSPR instruction that takes 1 special purpose register and produces an integer output register
void::model-function::ppc_insn_from_spr:itable_index index, model_data *model_ptr, const uint32_t int_mask, const unsigned nSPR
model_busy *busy_ptr;
while ((model_ptr->int_busy & int_mask) != 0 || model_ptr->spr_busy[nSPR] != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, 0, 0, nSPR);
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 |= int_mask;
busy_ptr->int_busy |= int_mask;
busy_ptr->nr_writebacks = 1;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, int_mask, 0, 0);
# Schedule an MTSPR instruction that takes 1 integer register and produces a special purpose output register
void::model-function::ppc_insn_to_spr:itable_index index, model_data *model_ptr, const uint32_t int_mask, const unsigned nSPR
model_busy *busy_ptr;
while ((model_ptr->int_busy & int_mask) != 0 || model_ptr->spr_busy[nSPR] != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, 0, 0, nSPR);
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->spr_busy = nSPR;
model_ptr->spr_busy[nSPR] = 1;
busy_ptr->nr_writebacks = 1;
TRACE(trace_model,("Making register %s busy.\n", spr_name(nSPR)));
# Schedule a MFCR instruction that moves the CR into an integer register
void::model-function::ppc_insn_mfcr:itable_index index, model_data *model_ptr, uint32_t int_mask
const uint32_t cr_mask = 0xff;
model_busy *busy_ptr;
while (((model_ptr->int_busy & int_mask) | (model_ptr->cr_fpscr_busy & cr_mask)) != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, 0, cr_mask, PPC_NO_SPR);
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 |= int_mask;
busy_ptr->int_busy |= int_mask;
busy_ptr->nr_writebacks = 1;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, int_mask, 0, 0);
# Schedule a MTCR instruction that moves an integer register into the CR
void::model-function::ppc_insn_mtcr:itable_index index, model_data *model_ptr, uint32_t int_mask, unsigned FXM
int f;
int nr_crs = 0;
uint32_t cr_mask = 0;
const model_time *normal_time = &model_ptr->timing[index];
static const model_time ppc604_1bit_time = { PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0 };
model_busy *busy_ptr;
for (f = 0; f < 8; f++) {
if (FXM & (0x80 >> f)) {
cr_mask |= (1 << f);
nr_crs++;
}
}
while (((model_ptr->int_busy & int_mask) | (model_ptr->cr_fpscr_busy & cr_mask)) != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_busy_p(model_ptr, int_mask, 0, cr_mask, PPC_NO_SPR);
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
/* If only one CR is being moved, use the SCIU, not the MCIU on the 604 */
if (CURRENT_MODEL == MODEL_ppc604 && nr_crs == 1) {
normal_time = &ppc604_1bit_time;
}
busy_ptr = model_wait_for_unit(index, model_ptr, normal_time);
busy_ptr->cr_fpscr_busy |= cr_mask;
model_ptr->cr_fpscr_busy |= cr_mask;
model_ptr->nr_mtcrf_crs[nr_crs]++;
busy_ptr->nr_writebacks = 1;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_make_busy(model_ptr, 0, 0, cr_mask);
model_data *::model-function::model_create:cpu *processor
model_data *model_ptr = ZALLOC(model_data);
model_ptr->name = model_name[CURRENT_MODEL];
model_ptr->timing = model_time_mapping[CURRENT_MODEL];
model_ptr->processor = processor;
model_ptr->nr_cycles = 1;
model_ptr->busy_tail = &model_ptr->busy_head;
switch (CURRENT_MODEL) {
case MODEL_ppc601: model_ptr->max_nr_writebacks = 1; break; /* ??? */
case MODEL_ppc603: model_ptr->max_nr_writebacks = 2; break;
case MODEL_ppc603e: model_ptr->max_nr_writebacks = 2; break;
case MODEL_ppc604: model_ptr->max_nr_writebacks = 2; break;
default: error ("Unknown model %d\n", CURRENT_MODEL);
}
return model_ptr;
void::model-function::model_init:model_data *model_ptr
void::model-function::model_halt:model_data *model_ptr
/* Let pipeline drain */
while (model_ptr->busy_head.next)
model_new_cycle(model_ptr);
unsigned_word::model-function::model_get_number_of_stalls:model_data *model_ptr
return (model_ptr->nr_stalls_data
+ model_ptr->nr_stalls_unit
+ model_ptr->nr_stalls_serialize
+ model_ptr->nr_stalls_writeback);
unsigned_word::model-function::model_get_number_of_cycles:model_data *model_ptr
return (model_ptr->nr_cycles);
model_print *::model-function::model_mon_info:model_data *model_ptr
model_print *head;
model_print *tail;
ppc_function_unit i;
count_type nr_insns;
int j;
head = tail = ZALLOC(model_print);
tail->count = model_ptr->nr_cycles;
tail->name = "cycle";
tail->suffix_plural = "s";
tail->suffix_singular = "";
if (model_ptr->nr_stalls_data) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_stalls_data;
tail->name = "stall";
tail->suffix_plural = "s waiting for data";
tail->suffix_singular = " waiting for data";
}
if (model_ptr->nr_stalls_unit) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_stalls_unit;
tail->name = "stall";
tail->suffix_plural = "s waiting for a function unit";
tail->suffix_singular = " waiting for a function unit";
}
if (model_ptr->nr_stalls_serialize) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_stalls_serialize;
tail->name = "stall";
tail->suffix_plural = "s waiting for serialization";
tail->suffix_singular = " waiting for serialization";
}
if (model_ptr->nr_stalls_writeback) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_stalls_writeback;
tail->name = "";
tail->suffix_plural = "times a write-back slot was unavailable";
tail->suffix_singular = "time a writeback was unavailable";
}
if (model_ptr->nr_branches) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_branches;
tail->name = "branch";
tail->suffix_plural = "es";
tail->suffix_singular = "";
}
if (model_ptr->nr_branches_fallthrough) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_branches_fallthrough;
tail->name = "conditional branch";
tail->suffix_plural = "es fell through";
tail->suffix_singular = " fell through";
}
if (model_ptr->nr_branch_predict_trues) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_branch_predict_trues;
tail->name = "successful branch prediction";
tail->suffix_plural = "s";
tail->suffix_singular = "";
}
if (model_ptr->nr_branch_predict_falses) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_branch_predict_falses;
tail->name = "unsuccessful branch prediction";
tail->suffix_plural = "s";
tail->suffix_singular = "";
}
for (j = 0; j < ARRAY_SIZE (ppc_branch_conditional_name); j++) {
if (model_ptr->nr_branch_conditional[j]) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_branch_conditional[j];
tail->name = ppc_branch_conditional_name[j];
tail->suffix_plural = " conditional branches";
tail->suffix_singular = " conditional branch";
}
}
for (j = 0; j < 9; j++) {
if (model_ptr->nr_mtcrf_crs[j]) {
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_mtcrf_crs[j];
tail->name = ppc_nr_mtcrf_crs[j];
tail->suffix_plural = " instructions";
tail->suffix_singular = " instruction";
}
}
nr_insns = 0;
for (i = PPC_UNIT_BAD; i < nr_ppc_function_units; i++) {
if (model_ptr->nr_units[i]) {
nr_insns += model_ptr->nr_units[i];
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = model_ptr->nr_units[i];
tail->name = ppc_function_unit_name[i];
tail->suffix_plural = "s";
tail->suffix_singular = "";
}
}
tail->next = ZALLOC(model_print);
tail = tail->next;
tail->count = nr_insns;
tail->name = "instruction";
tail->suffix_plural = "s that were accounted for in timing info";
tail->suffix_singular = " that was accounted for in timing info";
tail->next = (model_print *)0;
return head;
void::model-function::model_mon_info_free:model_data *model_ptr, model_print *ptr
while (ptr) {
model_print *next = ptr->next;
free((void *)ptr);
ptr = next;
}
void::model-function::model_branches:model_data *model_ptr, int failed, int conditional
model_ptr->nr_units[PPC_UNIT_BPU]++;
if (failed)
model_ptr->nr_branches_fallthrough++;
else
model_ptr->nr_branches++;
if (conditional >= 0)
model_ptr->nr_branch_conditional[conditional]++;
model_new_cycle(model_ptr); /* A branch always ends the current cycle */
void::model-function::model_branch_predict:model_data *model_ptr, int success
if (success)
model_ptr->nr_branch_predict_trues++;
else
model_ptr->nr_branch_predict_falses++;
# The following (illegal) instruction is `known' by gen and is
# called when ever an illegal instruction is encountered
::internal::illegal
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
# The following (floating point unavailable) instruction is `known' by gen
# and is called when ever an a floating point instruction is to be
# executed but floating point is make unavailable by the MSR
::internal::floating_point_unavailable
floating_point_unavailable_interrupt(processor, cia);
#
# Floating point support functions
#
# Convert 32bit single to 64bit double
uint64_t::function::DOUBLE:uint32_t WORD
uint64_t FRT;
if (EXTRACTED32(WORD, 1, 8) > 0
&& EXTRACTED32(WORD, 1, 8) < 255) {
/* normalized operand */
int not_word_1_1 = !EXTRACTED32(WORD, 1, 1); /*2.6.3 bug*/
FRT = (INSERTED64(EXTRACTED32(WORD, 0, 1), 0, 1)
| INSERTED64(not_word_1_1, 2, 2)
| INSERTED64(not_word_1_1, 3, 3)
| INSERTED64(not_word_1_1, 4, 4)
| INSERTED64(EXTRACTED32(WORD, 2, 31), 5, (63 - 29)));
}
else if (EXTRACTED32(WORD, 1, 8) == 0
&& EXTRACTED32(WORD, 9, 31) != 0) {
/* denormalized operand */
int sign = EXTRACTED32(WORD, 0, 0);
int exp = -126;
uint64_t frac = INSERTED64(EXTRACTED32(WORD, 9, 31), 1, (52 - 29));
/* normalize the operand */
while (MASKED64(frac, 0, 0) == 0) {
frac <<= 1;
exp -= 1;
}
FRT = (INSERTED64(sign, 0, 0)
| INSERTED64(exp + 1023, 1, 11)
| INSERTED64(EXTRACTED64(frac, 1, 52), 12, 63));
}
else if (EXTRACTED32(WORD, 1, 8) == 255
|| EXTRACTED32(WORD, 1, 31) == 0) {
FRT = (INSERTED64(EXTRACTED32(WORD, 0, 1), 0, 1)
| INSERTED64(EXTRACTED32(WORD, 1, 1), 2, 2)
| INSERTED64(EXTRACTED32(WORD, 1, 1), 3, 3)
| INSERTED64(EXTRACTED32(WORD, 1, 1), 4, 4)
| INSERTED64(EXTRACTED32(WORD, 2, 31), 5, (63 - 29)));
}
else {
error("DOUBLE - unknown case\n");
FRT = 0;
}
return FRT;
# Convert 64bit single to 32bit double
uint32_t::function::SINGLE:uint64_t FRS
uint32_t WORD;
if (EXTRACTED64(FRS, 1, 11) > 896
|| EXTRACTED64(FRS, 1, 63) == 0) {
/* no denormalization required (includes Zero/Infinity/NaN) */
WORD = (INSERTED32(EXTRACTED64(FRS, 0, 1), 0, 1)
| INSERTED32(EXTRACTED64(FRS, 5, 34), 2, 31));
}
else if (874 <= EXTRACTED64(FRS, 1, 11)
&& EXTRACTED64(FRS, 1, 11) <= 896) {
/* denormalization required */
int sign = EXTRACTED64(FRS, 0, 0);
int exp = EXTRACTED64(FRS, 1, 11) - 1023;
uint64_t frac = (BIT64(0)
| INSERTED64(EXTRACTED64(FRS, 12, 63), 1, 52));
/* denormalize the operand */
while (exp < -126) {
frac = INSERTED64(EXTRACTED64(frac, 0, 62), 1, 63);
exp += 1;
}
WORD = (INSERTED32(sign, 0, 0)
| INSERTED32(0x00, 1, 8)
| INSERTED32(EXTRACTED64(frac, 1, 23), 9, 31));
}
else {
WORD = 0x0; /* ??? */
}
return WORD;
# round 64bit double to 64bit but single
void::function::Round_Single:cpu *processor, int sign, int *exp, uint64_t *frac_grx
/* comparisons ignore u bits */
uint64_t out;
int inc = 0;
int lsb = EXTRACTED64(*frac_grx, 23, 23);
int gbit = EXTRACTED64(*frac_grx, 24, 24);
int rbit = EXTRACTED64(*frac_grx, 25, 25);
int xbit = EXTRACTED64(*frac_grx, 26, 55) != 0;
if ((FPSCR & fpscr_rn) == fpscr_rn_round_to_nearest) {
if (lsb == 1 && gbit == 1) inc = 1;
if (lsb == 0 && gbit == 1 && rbit == 1) inc = 1;
if (lsb == 0 && gbit == 1 && xbit == 1) inc = 1;
}
if ((FPSCR & fpscr_rn) == fpscr_rn_round_towards_pos_infinity) {
if (sign == 0 && gbit == 1) inc = 1;
if (sign == 0 && rbit == 1) inc = 1;
if (sign == 0 && xbit == 1) inc = 1;
}
if ((FPSCR & fpscr_rn) == fpscr_rn_round_towards_neg_infinity) {
if (sign == 1 && gbit == 1) inc = 1;
if (sign == 1 && rbit == 1) inc = 1;
if (sign == 1 && xbit == 1) inc = 1;
}
/* work out addition in low 25 bits of out */
out = EXTRACTED64(*frac_grx, 0, 23) + inc;
*frac_grx = INSERTED64(out, 0, 23);
if (out & BIT64(64 - 23 - 1 - 1)) {
*frac_grx = (BIT64(0) |
INSERTED64(EXTRACTED64(*frac_grx, 0, 22), 1, 23));
*exp = *exp + 1;
}
/* frac_grx[24:52] = 0 already */
FPSCR_SET_FR(inc);
FPSCR_SET_FI(gbit || rbit || xbit);
#
void::function::Round_Integer:cpu *processor, int sign, uint64_t *frac, int *frac64, int gbit, int rbit, int xbit, fpscreg round_mode
int inc = 0;
if (round_mode == fpscr_rn_round_to_nearest) {
if (*frac64 == 1 && gbit == 1) inc = 1;
if (*frac64 == 0 && gbit == 1 && rbit == 1) inc = 1;
if (*frac64 == 0 && gbit == 1 && xbit == 1) inc = 1;
}
if (round_mode == fpscr_rn_round_towards_pos_infinity) {
if (sign == 0 && gbit == 1) inc = 1;
if (sign == 0 && rbit == 1) inc = 1;
if (sign == 0 && xbit == 1) inc = 1;
}
if (round_mode == fpscr_rn_round_towards_neg_infinity) {
if (sign == 1 && gbit == 1) inc = 1;
if (sign == 1 && rbit == 1) inc = 1;
if (sign == 1 && xbit == 1) inc = 1;
}
/* frac[0:64] = frac[0:64} + inc */
*frac += (*frac64 && inc ? 1 : 0);
*frac64 = (*frac64 + inc) & 0x1;
FPSCR_SET_FR(inc);
FPSCR_SET_FI(gbit | rbit | xbit);
void::function::Round_Float:cpu *processor, int sign, int *exp, uint64_t *frac, fpscreg round_mode
int carry_out;
int inc = 0;
int lsb = EXTRACTED64(*frac, 52, 52);
int gbit = EXTRACTED64(*frac, 53, 53);
int rbit = EXTRACTED64(*frac, 54, 54);
int xbit = EXTRACTED64(*frac, 55, 55);
if (round_mode == fpscr_rn_round_to_nearest) {
if (lsb == 1 && gbit == 1) inc = 1;
if (lsb == 0 && gbit == 1 && rbit == 1) inc = 1;
if (lsb == 0 && gbit == 1 && xbit == 1) inc = 1;
}
if (round_mode == fpscr_rn_round_towards_pos_infinity) {
if (sign == 0 && gbit == 1) inc = 1;
if (sign == 0 && rbit == 1) inc = 1;
if (sign == 0 && xbit == 1) inc = 1;
}
if (round_mode == fpscr_rn_round_towards_neg_infinity) {
if (sign == 1 && gbit == 1) inc = 1;
if (sign == 1 && rbit == 1) inc = 1;
if (sign == 1 && xbit == 1) inc = 1;
}
/* frac//carry_out = frac + inc */
*frac = (*frac >> 1) + (INSERTED64(inc, 52, 52) >> 1);
carry_out = EXTRACTED64(*frac, 0, 0);
*frac <<= 1;
if (carry_out == 1) *exp = *exp + 1;
FPSCR_SET_FR(inc);
FPSCR_SET_FI(gbit | rbit | xbit);
FPSCR_SET_XX(FPSCR & fpscr_fi);
# conversion of FP to integer
void::function::convert_to_integer:cpu *processor, unsigned_word cia, uint64_t *frt, uint64_t frb, fpscreg round_mode, int tgt_precision
int i;
int exp = 0;
uint64_t frac = 0;
int frac64 = 0;
int gbit = 0;
int rbit = 0;
int xbit = 0;
int sign = EXTRACTED64(frb, 0, 0);
/***/
if (EXTRACTED64(frb, 1, 11) == 2047 && EXTRACTED64(frb, 12, 63) == 0)
GOTO(Infinity_Operand);
if (EXTRACTED64(frb, 1, 11) == 2047 && EXTRACTED64(frb, 12, 12) == 0)
GOTO(SNaN_Operand);
if (EXTRACTED64(frb, 1, 11) == 2047 && EXTRACTED64(frb, 12, 12) == 1)
GOTO(QNaN_Operand);
if (EXTRACTED64(frb, 1, 11) > 1086) GOTO(Large_Operand);
if (EXTRACTED64(frb, 1, 11) > 0) exp = EXTRACTED64(frb, 1, 11) - 1023;
if (EXTRACTED64(frb, 1, 11) == 0) exp = -1022;
if (EXTRACTED64(frb, 1, 11) > 0) { /* normal */
frac = BIT64(1) | INSERTED64(EXTRACTED64(frb, 12, 63), 2, 53);
frac64 = 0;
}
if (EXTRACTED64(frb, 1, 11) == 0) { /* denorm */
frac = INSERTED64(EXTRACTED64(frb, 12, 63), 2, 53);
frac64 = 0;
}
gbit = 0, rbit = 0, xbit = 0;
for (i = 1; i <= 63 - exp; i++) {
xbit = rbit | xbit;
rbit = gbit;
gbit = frac64;
frac64 = EXTRACTED64(frac, 63, 63);
frac = INSERTED64(EXTRACTED64(frac, 0, 62), 1, 63);
}
Round_Integer(processor, sign, &frac, &frac64, gbit, rbit, xbit, round_mode);
if (sign == 1) { /* frac[0:64] = ~frac[0:64] + 1 */
frac = ~frac;
frac64 ^= 1;
frac += (frac64 ? 1 : 0);
frac64 = (frac64 + 1) & 0x1;
}
if (tgt_precision == 32 /* can ignore frac64 in compare */
&& (int64_t)frac > (int64_t)MASK64(33+1, 63)/*2^31-1 >>1*/)
GOTO(Large_Operand);
if (tgt_precision == 64 /* can ignore frac64 in compare */
&& (int64_t)frac > (int64_t)MASK64(1+1, 63)/*2^63-1 >>1*/)
GOTO(Large_Operand);
if (tgt_precision == 32 /* can ignore frac64 in compare */
&& (int64_t)frac < (int64_t)MASK64(0, 32+1)/*-2^31 >>1*/)
GOTO(Large_Operand);
if (tgt_precision == 64 /* can ignore frac64 in compare */
&& (int64_t)frac < (int64_t)MASK64(0, 0+1)/*-2^63 >>1*/)
GOTO(Large_Operand);
FPSCR_SET_XX(FPSCR & fpscr_fi);
if (tgt_precision == 32)
*frt = MASKED64(*frt, 0, 31) | (EXTRACTED64(frac, 33, 63) << 1) | frac64;
if (tgt_precision == 64)
*frt = (EXTRACTED64(frac, 1, 63) << 1) | frac64;
/*FPSCR[fprf] = undefined */
GOTO(Done);
/**/
LABEL(Infinity_Operand):
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
FPSCR_OR_VX(fpscr_vxcvi);
if ((FPSCR & fpscr_ve) == 0) {
if (tgt_precision == 32) {
if (sign == 0) *frt = MASKED64(*frt, 0, 31) | 0x7FFFFFFF;
if (sign == 1) *frt = MASKED64(*frt, 0, 31) | 0x80000000;
}
else {
if (sign == 0) *frt = MASK64(1, 63); /*0x7FFF_FFFF_FFFF_FFFF*/
if (sign == 1) *frt = BIT64(0); /*0x8000_0000_0000_0000*/
}
/* FPSCR[FPRF] = undefined */
}
GOTO(Done);
/**/
LABEL(SNaN_Operand):
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
FPSCR_OR_VX(fpscr_vxsnan | fpscr_vxcvi);
if ((FPSCR & fpscr_ve) == 0) {
if (tgt_precision == 32) *frt = MASKED64(*frt, 0, 31) | 0x80000000;
if (tgt_precision == 64) *frt = BIT64(0); /*0x8000_0000_0000_0000*/
/* FPSCR[fprf] = undefined */
}
GOTO(Done);
/**/
LABEL(QNaN_Operand):
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
FPSCR_OR_VX(fpscr_vxcvi);
if ((FPSCR & fpscr_ve) == 0) {
if (tgt_precision == 32) *frt = MASKED64(*frt, 0, 31) | 0x80000000;
if (tgt_precision == 64) *frt = BIT64(0);/*0x8000_0000_0000_0000*/
/* FPSCR[fprf] = undefined */
}
GOTO(Done);
/**/
LABEL(Large_Operand):
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
FPSCR_OR_VX(fpscr_vxcvi);
if ((FPSCR & fpscr_ve) == 0) {
if (tgt_precision == 32) {
if (sign == 0) *frt = MASKED64(*frt, 0, 31) | 0x7fffffff;
if (sign == 1) *frt = MASKED64(*frt, 0, 31) | 0x80000000;
}
else {
if (sign == 0) *frt = MASK64(1, 63); /*0x7FFF_FFFF_FFFF_FFFF*/
if (sign == 1) *frt = BIT64(0); /*0x8000_0000_0000_0000*/
}
/* FPSCR[fprf] = undefined */
}
/**/
LABEL(Done):;
# extract out raw fields of a FP number
int::function::sign:uint64_t FRS
return (MASKED64(FRS, 0, 0)
? -1
: 1);
int::function::biased_exp:uint64_t frs, int single
if (single)
return EXTRACTED64(frs, 1, 8);
else
return EXTRACTED64(frs, 1, 11);
uint64_t::function::fraction:uint64_t frs, int single
if (single)
return EXTRACTED64(frs, 9, 31);
else
return EXTRACTED64(frs, 12, 63);
# a number?, each of the below return +1 or -1 (based on sign bit)
# if true.
int::function::is_nor:uint64_t frs, int single
int exp = biased_exp(frs, single);
return (exp >= 1
&& exp <= (single ? 254 : 2046));
int::function::is_zero:uint64_t FRS
return (MASKED64(FRS, 1, 63) == 0
? sign(FRS)
: 0);
int::function::is_den:uint64_t frs, int single
int exp = biased_exp(frs, single);
uint64_t frac = fraction(frs, single);
return (exp == 0 && frac != 0
? sign(frs)
: 0);
int::function::is_inf:uint64_t frs, int single
int exp = biased_exp(frs, single);
uint64_t frac = fraction(frs, single);
return (exp == (single ? 255 : 2047) && frac == 0
? sign(frs)
: 0);
int::function::is_NaN:uint64_t frs, int single
int exp = biased_exp(frs, single);
uint64_t frac = fraction(frs, single);
return (exp == (single ? 255 : 2047) && frac != 0
? sign(frs)
: 0);
int::function::is_SNaN:uint64_t frs, int single
return (is_NaN(frs, single)
&& !(frs & (single ? MASK64(9, 9) : MASK64(12, 12)))
? sign(frs)
: 0);
int::function::is_QNaN:uint64_t frs, int single
return (is_NaN(frs, single) && !is_SNaN(frs, single));
int::function::is_less_than:uint64_t *fra, uint64_t *frb
return *(double*)fra < *(double*)frb;
int::function::is_greater_than:uint64_t *fra, uint64_t *frb
return *(double*)fra > *(double*)frb;
int::function::is_equan_to:uint64_t *fra, uint64_t *frb
return *(double*)fra == *(double*)frb;
# which quiet nan should become the result
uint64_t::function::select_qnan:uint64_t fra, uint64_t frb, uint64_t frc, int instruction_is_frsp, int generate_qnan, int single
uint64_t frt = 0;
if (is_NaN(fra, single))
frt = fra;
else if (is_NaN(frb, single))
if (instruction_is_frsp)
frt = MASKED64(frb, 0, 34);
else
frt = frb;
else if (is_NaN(frc, single))
frt = frc;
else if (generate_qnan)
frt = MASK64(1, 12); /* 0x7FF8_0000_0000_0000 */
else
error("select_qnan - default reached\n");
return frt;
# detect invalid operation
int::function::is_invalid_operation:cpu *processor, unsigned_word cia, uint64_t fra, uint64_t frb, fpscreg check, int single, int negate
int fail = 0;
if ((check & fpscr_vxsnan)
&& (is_SNaN(fra, single) || is_SNaN(frb, single))) {
FPSCR_OR_VX(fpscr_vxsnan);
fail = 1;
}
if ((check & fpscr_vxisi)
&& (is_inf(fra, single) && is_inf(frb, single))
&& ((negate && sign(fra) != sign(frb))
|| (!negate && sign(fra) == sign(frb)))) {
/*FIXME: don't handle inf-inf VS inf+-inf */
FPSCR_OR_VX(fpscr_vxisi);
fail = 1;
}
if ((check & fpscr_vxidi)
&& (is_inf(fra, single) && is_inf(frb, single))) {
FPSCR_OR_VX(fpscr_vxidi);
fail = 1;
}
if ((check & fpscr_vxzdz)
&& (is_zero(fra) && is_zero(frb))) {
FPSCR_OR_VX(fpscr_vxzdz);
fail = 1;
}
if ((check & fpscr_vximz)
&& (is_zero(fra) && is_inf(frb, single))) {
FPSCR_OR_VX(fpscr_vximz);
fail = 1;
}
if ((check & fpscr_vxvc)
&& (is_NaN(fra, single) || is_NaN(frb, single))) {
FPSCR_OR_VX(fpscr_vxvc);
fail = 1;
}
if ((check & fpscr_vxsoft)) {
FPSCR_OR_VX(fpscr_vxsoft);
fail = 1;
}
if ((check & fpscr_vxsqrt)
&& sign(fra) < 0) {
FPSCR_OR_VX(fpscr_vxsqrt);
fail = 1;
}
/* if ((check && fpscr_vxcvi) {
&& (is_inf(fra, single) || is_NaN(fra, single) || is_large(fra, single)))
FPSCR_OR_VX(fpscr_vxcvi);
fail = 1;
}
*/
return fail;
# handle case of invalid operation
void::function::invalid_arithemetic_operation:cpu *processor, unsigned_word cia, uint64_t *frt, uint64_t fra, uint64_t frb, uint64_t frc, int instruction_is_frsp, int instruction_is_convert_to_64bit, int instruction_is_convert_to_32bit, int single
if (FPSCR & fpscr_ve) {
/* invalid operation exception enabled */
/* FRT unchaged */
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
/* fpscr_FPRF unchanged */
}
else {
/* invalid operation exception disabled */
if (instruction_is_convert_to_64bit) {
error("oopsi");
}
else if (instruction_is_convert_to_32bit) {
error("oopsi");
}
else { /* arrith, frsp */
*frt = select_qnan(fra, frb, frc,
instruction_is_frsp, 1/*generate*/, single);
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
FPSCR_SET_FPRF(fpscr_rf_quiet_nan);
}
}
# detect divide by zero
int::function::is_invalid_zero_divide:cpu *processor, unsigned_word cia, uint64_t fra, uint64_t frb, int single
int fail = 0;
if (is_zero (frb)) {
FPSCR_SET_ZX (1);
fail = 1;
}
return fail;
# handle case of invalid operation
void::function::invalid_zero_divide_operation:cpu *processor, unsigned_word cia, uint64_t *frt, uint64_t fra, uint64_t frb, int single
if (FPSCR & fpscr_ze) {
/* zero-divide exception enabled */
/* FRT unchaged */
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
/* fpscr_FPRF unchanged */
}
else {
/* zero-divide exception disabled */
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
if ((sign (fra) < 0 && sign (frb) < 0)
|| (sign (fra) > 0 && sign (frb) > 0)) {
*frt = MASK64 (1, 11); /* 0 : 2047 : 0..0 */
FPSCR_SET_FPRF(fpscr_rf_pos_infinity);
}
else {
*frt = MASK64 (0, 11); /* 1 : 2047 : 0..0 */
FPSCR_SET_FPRF(fpscr_rf_neg_infinity);
}
}
#
# 0.0.0.0 Illegal instruction used for kernel mode emulation
#
0.0,6./,11./,16./,21./,31.1:X:::instruction_call
if (!os_emul_instruction_call(processor, cia, real_addr(cia, 1)))
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
#
# I.2.4.1 Branch Instructions
#
0.18,6.LI,30.AA,31.LK:I:::Branch
*601: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603e:PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
/* option_mpc860c0:
No problem here because this branch is predicted taken (unconditional). */
if (AA) NIA = IEA(EXTS(LI_0b00));
else NIA = IEA(CIA + EXTS(LI_0b00));
if (LK) LR = (spreg)CIA+4;
if (CURRENT_MODEL_ISSUE > 0)
model_branches(cpu_model(processor), 1, -1);
0.16,6.BO,11.BI,16.BD,30.AA,31.LK:B:::Branch Conditional
*601: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603e:PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
int M, ctr_ok, cond_ok, succeed;
if (CURRENT_MODEL_ISSUE > 0 && ! BO{0})
model_wait_for_cr(cpu_model(processor), BIT32_BI);
if (is_64bit_implementation && is_64bit_mode) M = 0;
else M = 32;
if (!BO{2}) CTR = CTR - 1;
ctr_ok = BO{2} || ((MASKED(CTR, M, 63) != 0) != (BO{3}));
cond_ok = BO{0} || ((CR{BI}) == (BO{1}));
if (ctr_ok && cond_ok) {
if (AA) NIA = IEA(EXTS(BD_0b00));
else NIA = IEA(CIA + EXTS(BD_0b00));
succeed = 1;
}
else
succeed = 0;
if (LK) LR = (spreg)IEA(CIA + 4);
if (option_mpc860c0 && (!BO{0} || !BO{2}) && !BO{4}) {
/* This branch is predicted as "normal".
If this is a forward branch and it is near the end of a page,
we've detected a problematic branch. */
if (succeed && NIA > CIA) {
if (MPC860C0_PAGE_SIZE - (CIA & (MPC860C0_PAGE_SIZE-1)) <= option_mpc860c0)
program_interrupt(processor, cia, mpc860c0_instruction_program_interrupt);
}
}
if (CURRENT_MODEL_ISSUE > 0)
model_branches(cpu_model(processor), succeed, BO);
if (! BO{0}) {
int reverse;
if (BO{4}) { /* branch prediction bit set, reverse sense of test */
reverse = EXTS(BD_0b00) < 0;
} else { /* branch prediction bit not set */
reverse = EXTS(BD_0b00) >= 0;
}
if (CURRENT_MODEL_ISSUE > 0)
model_branch_predict(cpu_model(processor), reverse ? !succeed : succeed);
}
0.19,6.BO,11.BI,16./,21.16,31.LK:XL:::Branch Conditional to Link Register
*601: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603e:PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
int M, ctr_ok, cond_ok, succeed;
if (is_64bit_implementation && is_64bit_mode) M = 0;
else M = 32;
if (CURRENT_MODEL_ISSUE > 0 && ! BO{0})
model_wait_for_cr(cpu_model(processor), BIT32_BI);
if (!BO{2}) CTR = CTR - 1;
ctr_ok = BO{2} || ((MASKED(CTR, M, 63) != 0) != BO{3});
cond_ok = BO{0} || (CR{BI} == BO{1});
if (ctr_ok && cond_ok) {
NIA = IEA(LR_0b00);
succeed = 1;
}
else
succeed = 0;
if (LK) LR = (spreg)IEA(CIA + 4);
if (option_mpc860c0 && (!BO{0} || !BO{2}) && !BO{4}) {
/* This branch is predicted as not-taken.
If this is a forward branch and it is near the end of a page,
we've detected a problematic branch. */
if (succeed && NIA > CIA) {
if (MPC860C0_PAGE_SIZE - (CIA & (MPC860C0_PAGE_SIZE-1)) <= option_mpc860c0)
program_interrupt(processor, cia, mpc860c0_instruction_program_interrupt);
}
}
if (CURRENT_MODEL_ISSUE > 0) {
model_branches(cpu_model(processor), succeed, BO);
if (! BO{0})
model_branch_predict(cpu_model(processor), BO{4} ? !succeed : succeed);
}
0.19,6.BO,11.BI,16./,21.528,31.LK:XL:::Branch Conditional to Count Register
*601: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*603e:PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
int cond_ok, succeed;
if (CURRENT_MODEL_ISSUE > 0 && ! BO{0})
model_wait_for_cr(cpu_model(processor), BIT32_BI);
cond_ok = BO{0} || (CR{BI} == BO{1});
if (cond_ok) {
NIA = IEA(CTR_0b00);
succeed = 1;
}
else
succeed = 0;
if (LK) LR = (spreg)IEA(CIA + 4);
if (option_mpc860c0 && (!BO{0} || !BO{2}) && !BO{4}) {
/* This branch is predicted as not-taken.
If this is a forward branch and it is near the end of a page,
we've detected a problematic branch. */
if (succeed && NIA > CIA) {
if (MPC860C0_PAGE_SIZE - (CIA & (MPC860C0_PAGE_SIZE-1)) <= option_mpc860c0)
program_interrupt(processor, cia, mpc860c0_instruction_program_interrupt);
}
}
if (CURRENT_MODEL_ISSUE > 0) {
model_branches(cpu_model(processor), succeed, BO);
if (! BO{0})
model_branch_predict(cpu_model(processor), BO{4} ? !succeed : succeed);
}
#
# I.2.4.2 System Call Instruction
#
0.17,6./,11./,16./,30.1,31./:SC:::System Call
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (CURRENT_MODEL_ISSUE > 0)
model_serialize(MY_INDEX, cpu_model(processor));
system_call_interrupt(processor, cia);
#
# I.2.4.3 Condition Register Logical Instructions
#
0.19,6.BT,11.BA,16.BB,21.257,31./:XL::crand:Condition Register AND
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, CR{BA} && CR{BB});
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.449,31./:XL::cror:Condition Register OR
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, CR{BA} || CR{BB});
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.193,31./:XL::crxor:Condition Register XOR
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, CR{BA} != CR{BB});
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.225,31./:XL::crnand:Condition Register NAND
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, !(CR{BA} && CR{BB}));
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.33,31./:XL::crnor:Condition Register NOR
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, !(CR{BA} || CR{BB}));
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.289,31./:XL::creqv:Condition Register Equivalent
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, CR{BA} == CR{BB});
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.129,31./:XL::crandc:Condition Register AND with Complement
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, CR{BA} && !CR{BB});
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
0.19,6.BT,11.BA,16.BB,21.417,31./:XL::crorc:Condition Register OR with Complement
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
BLIT32(CR, BT, CR{BA} || !CR{BB});
PPC_INSN_CR(BT_BITMASK, BA_BITMASK | BB_BITMASK);
#
# I.2.4.4 Condition Register Field Instruction
#
0.19,6.BF,9./,11.BFA,14./,16./,21.0,31./:XL:::Move Condition Register Field
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 1, 0
MBLIT32(CR, 4*BF, 4*BF+3, EXTRACTED32(CR, 4*BFA, 4*BFA+3));
PPC_INSN_CR(BF_BITMASK, 1 << BFA);
#
# I.3.3.2 Fixed-Point Load Instructions
#
0.34,6.RT,11.RA,16.D:D:::Load Byte and Zero
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
*rT = MEM(unsigned, EA, 1);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.RT,11.RA,16.RB,21.87,31./:X:::Load Byte and Zero Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*rT = MEM(unsigned, EA, 1);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.35,6.RT,11.RA,16.D:D:::Load Byte and Zero with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
*rT = MEM(unsigned, EA, 1);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK, 0);
0.31,6.RT,11.RA,16.RB,21.119,31./:X:::Load Byte and Zero with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
*rT = MEM(unsigned, EA, 1);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK | RB_BITMASK, 0);
0.40,6.RT,11.RA,16.D:D:::Load Halfword and Zero
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
*rT = MEM(unsigned, EA, 2);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.RT,11.RA,16.RB,21.279,31./:X:::Load Halfword and Zero Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*rT = MEM(unsigned, EA, 2);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.41,6.RT,11.RA,16.D:D:::Load Halfword and Zero with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
*rT = MEM(unsigned, EA, 2);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK, 0);
0.31,6.RT,11.RA,16.RB,21.311,31./:X:::Load Halfword and Zero with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
*rT = MEM(unsigned, EA, 2);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK | RB_BITMASK, 0);
0.42,6.RT,11.RA,16.D:D:::Load Halfword Algebraic
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
*rT = MEM(signed, EA, 2);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.RT,11.RA,16.RB,21.343,31./:X:::Load Halfword Algebraic Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*rT = MEM(signed, EA, 2);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.43,6.RT,11.RA,16.D:D:::Load Halfword Algebraic with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
*rT = MEM(signed, EA, 2);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK, 0);
0.31,6.RT,11.RA,16.RB,21.375,31./:X:::Load Halfword Algebraic with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
*rT = MEM(signed, EA, 2);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK | RB_BITMASK, 0);
0.32,6.RT,11.RA,16.D:D:::Load Word and Zero
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
*rT = MEM(unsigned, EA, 4);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.RT,11.RA,16.RB,21.23,31./:X:::Load Word and Zero Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*rT = MEM(unsigned, EA, 4);
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.33,6.RT,11.RA,16.D:D:::Load Word and Zero with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
*rT = MEM(unsigned, EA, 4);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK, 0);
0.31,6.RT,11.RA,16.RB,21.55,31./:X:::Load Word and Zero with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
unsigned_word EA;
if (RA_is_0 || RA == RT)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
*rT = MEM(unsigned, EA, 4);
*rA = EA;
PPC_INSN_INT(RT_BITMASK | RA_BITMASK, RA_BITMASK | RB_BITMASK, 0);
0.58,6.RT,11.RA,16.DS,30.2:DS:64::Load Word Algebraic
# unsigned_word b;
# unsigned_word EA;
# if (RA_is_0) b = 0;
# else b = *rA;
# EA = b + EXTS(DS_0b00);
# *rT = MEM(signed, EA, 4);
0.31,6.RT,11.RA,16.RB,21.341,31./:X:64::Load Word Algebraic Indexed
# unsigned_word b;
# unsigned_word EA;
# if (RA_is_0) b = 0;
# else b = *rA;
# EA = b + *rB;;
# *rT = MEM(signed, EA, 4);
0.31,6.RT,11.RA,16.RB,21.373,31./:X:64::Load Word Algebraic with Update Indexed
# unsigned_word EA;
# if (RA_is_0 || RA == RT)
# program_interrupt(processor, cia
# illegal_instruction_program_interrupt);
# EA = *rA + *rB;
# *rT = MEM(signed, EA, 4);
# *rA = EA;
0.58,6.RT,11.RA,16.DS,30.0:DS:64::Load Doubleword
# unsigned_word b;
# unsigned_word EA;
# if (RA_is_0) b = 0;
# else b = *rA;
# EA = b + EXTS(DS_0b00);
# *rT = MEM(unsigned, EA, 8);
0.31,6.RT,11.RA,16.RB,21.21,31./:X:64::Load Doubleword Indexed
# unsigned_word b;
# unsigned_word EA;
# if (RA_is_0) b = 0;
# else b = *rA;
# EA = b + *rB;
# *rT = MEM(unsigned, EA, 8);
0.58,6.RT,11.RA,16.DS,30.1:DS:64::Load Doubleword with Update
# unsigned_word EA;
# if (RA_is_0 || RA == RT)
# program_interrupt(processor, cia
# illegal_instruction_program_interrupt);
# EA = *rA + EXTS(DS_0b00);
# *rT = MEM(unsigned, EA, 8);
# *rA = EA;
0.31,6.RT,11.RA,16.RB,21.53,31./:DS:64::Load Doubleword with Update Indexed
# unsigned_word EA;
# if (RA_is_0 || RA == RT)
# program_interrupt(processor, cia
# illegal_instruction_program_interrupt);
# EA = *rA + *rB;
# *rT = MEM(unsigned, EA, 8);
# *rA = EA;
#
# I.3.3.3 Fixed-Point Store Instructions
#
0.38,6.RS,11.RA,16.D:D:::Store Byte
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
STORE(EA, 1, *rS);
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.215,31./:X:::Store Byte Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 1, *rS);
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 0);
0.39,6.RS,11.RA,16.D:D:::Store Byte with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
STORE(EA, 1, *rS);
*rA = EA;
PPC_INSN_INT(RA_BITMASK, RA_BITMASK | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.247,31./:X:::Store Byte with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
STORE(EA, 1, *rS);
*rA = EA;
PPC_INSN_INT(RA_BITMASK, RA_BITMASK | RB_BITMASK | RS_BITMASK, 0);
0.44,6.RS,11.RA,16.D:D:::Store Half Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
STORE(EA, 2, *rS);
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.407,31./:X:::Store Half Word Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 2, *rS);
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 0);
0.45,6.RS,11.RA,16.D:D:::Store Half Word with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
STORE(EA, 2, *rS);
*rA = EA;
PPC_INSN_INT(RA_BITMASK, RA_BITMASK | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.439,31./:X:::Store Half Word with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
STORE(EA, 2, *rS);
*rA = EA;
PPC_INSN_INT(RA_BITMASK, RA_BITMASK | RB_BITMASK | RS_BITMASK, 0);
0.36,6.RS,11.RA,16.D:D:::Store Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
STORE(EA, 4, *rS);
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.151,31./:X:::Store Word Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 4, *rS);
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 0);
0.37,6.RS,11.RA,16.D:D:::Store Word with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
STORE(EA, 4, *rS);
*rA = EA;
PPC_INSN_INT(RA_BITMASK, RA_BITMASK | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.183,31./:X:::Store Word with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
STORE(EA, 4, *rS);
*rA = EA;
PPC_INSN_INT(RA_BITMASK, RA_BITMASK | RB_BITMASK | RS_BITMASK, 0);
0.62,6.RS,11.RA,16.DS,30.0:DS:64::Store Doubleword
# unsigned_word b;
# unsigned_word EA;
# if (RA_is_0) b = 0;
# else b = *rA;
# EA = b + EXTS(DS_0b00);
# STORE(EA, 8, *rS);
0.31,6.RS,11.RA,16.RB,21.149,31./:X:64::Store Doubleword Indexed
# unsigned_word b;
# unsigned_word EA;
# if (RA_is_0) b = 0;
# else b = *rA;
# EA = b + *rB;
# STORE(EA, 8, *rS);
0.62,6.RS,11.RA,16.DS,30.1:DS:64::Store Doubleword with Update
# unsigned_word EA;
# if (RA_is_0)
# program_interrupt(processor, cia
# illegal_instruction_program_interrupt);
# EA = *rA + EXTS(DS_0b00);
# STORE(EA, 8, *rS);
# *rA = EA;
0.31,6.RS,11.RA,16.RB,21.181,31./:X:64::Store Doubleword with Update Indexed
# unsigned_word EA;
# if (RA_is_0)
# program_interrupt(processor, cia
# illegal_instruction_program_interrupt);
# EA = *rA + *rB;
# STORE(EA, 8, *rS);
# *rA = EA;
#
# I.3.3.4 Fixed-Point Load and Store with Byte Reversal Instructions
#
0.31,6.RT,11.RA,16.RB,21.790,31./:X:::Load Halfword Byte-Reverse Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*rT = SWAP_2(MEM(unsigned, EA, 2));
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.31,6.RT,11.RA,16.RB,21.534,31./:X:::Load Word Byte-Reverse Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*rT = SWAP_4(MEM(unsigned, EA, 4));
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.918,31./:X:::Store Half Word Byte-Reversed Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 2, SWAP_2(*rS));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.662,31./:X:::Store Word Byte-Reversed Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 4, SWAP_4(*rS));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 0);
#
# I.3.3.5 Fixed-Point Load and Store Multiple Instrctions
#
0.46,6.RT,11.RA,16.D:D:::Load Multiple Word
unsigned_word EA;
unsigned_word b;
int r;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
r = RT;
if (RA >= r)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
if (CURRENT_ALIGNMENT == STRICT_ALIGNMENT || (EA % 4 != 0))
alignment_interrupt(processor, cia, EA);
while (r <= 31) {
GPR(r) = MEM(unsigned, EA, 4);
r = r + 1;
EA = EA + 4;
}
0.47,6.RS,11.RA,16.D:D:::Store Multiple Word
unsigned_word EA;
unsigned_word b;
int r;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
if (CURRENT_ALIGNMENT == STRICT_ALIGNMENT
|| (EA % 4 != 0))
alignment_interrupt(processor, cia, EA);
r = RS;
while (r <= 31) {
STORE(EA, 4, GPR(r));
r = r + 1;
EA = EA + 4;
}
#
# I.3.3.6 Fixed-Point Move Assist Instructions
#
0.31,6.RT,11.RA,16.NB,21.597,31./:X:::Load String Word Immediate
unsigned_word EA;
int n;
int r;
int i;
int nr;
if (RA_is_0) EA = 0;
else EA = *rA;
if (NB == 0) n = 32;
else n = NB;
r = RT - 1;
i = 32;
nr = (n + 3) / 4;
if ((RT + nr >= 32)
? (RA >= RT || RA < (RT + nr) % 32)
: (RA >= RT && RA < RT + nr))
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
if (CURRENT_ALIGNMENT == STRICT_ALIGNMENT)
alignment_interrupt(processor, cia, EA);
while (n > 0) {
if (i == 32) {
r = (r + 1) % 32;
GPR(r) = 0;
}
GPR(r) |= INSERTED(MEM(unsigned, EA, 1), i, i+7);
i = i + 8;
if (i == 64) i = 32;
EA = EA + 1;
n = n - 1;
}
0.31,6.RT,11.RA,16.RB,21.533,31./:X:::Load String Word Indexed
unsigned_word EA;
unsigned_word b;
int n;
int r;
int i;
int nr;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
n = EXTRACTED32(XER, 25, 31);
r = RT - 1;
i = 32;
nr = (n + 3) / 4;
if (((RT + nr >= 32)
? ((RA >= RT || RA < (RT + nr) % 32)
|| (RB >= RT || RB < (RT + nr) % 32))
: ((RA >= RT && RA < RT + nr)
|| (RB >= RT && RB < RT + nr)))
|| (RT == RA || RT == RB))
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
if (CURRENT_ALIGNMENT == STRICT_ALIGNMENT)
alignment_interrupt(processor, cia, EA);
while (n > 0) {
if (i == 32) {
r = (r + 1) % 32;
GPR(r) = 0;
}
GPR(r) |= INSERTED(MEM(unsigned, EA, 1), i, i+7);
i = i + 8;
if (i == 64) i = 32;
EA = EA + 1;
n = n - 1;
}
0.31,6.RS,11.RA,16.NB,21.725,31./:X:::Store String Word Immedate
unsigned_word EA;
int n;
int r;
int i;
if (RA_is_0) EA = 0;
else EA = *rA;
if (NB == 0) n = 32;
else n = NB;
r = RS - 1;
i = 32;
if (CURRENT_ALIGNMENT == STRICT_ALIGNMENT)
alignment_interrupt(processor, cia, EA);
while (n > 0) {
if (i == 32) r = (r + 1) % 32;
STORE(EA, 1, EXTRACTED(GPR(r), i, i+7));
i = i + 8;
if (i == 64) i = 32;
EA = EA + 1;
n = n - 1;
}
0.31,6.RS,11.RA,16.RB,21.661,31./:X:::Store String Word Indexed
unsigned_word EA;
unsigned_word b;
int n;
int r;
int i;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
if (CURRENT_ALIGNMENT == STRICT_ALIGNMENT)
alignment_interrupt(processor, cia, EA);
n = EXTRACTED32(XER, 25, 31);
r = RS - 1;
i = 32;
while (n > 0) {
if (i == 32) r = (r + 1) % 32;
STORE(EA, 1, EXTRACTED(GPR(r), i, i+7));
i = i + 8;
if (i == 64) i = 32;
EA = EA + 1;
n = n - 1;
}
#
# I.3.3.7 Storage Synchronization Instructions
#
# HACK: Rather than monitor addresses looking for a reason
# to cancel a reservation. This code instead keeps
# a copy of the data read from memory. Before performing
# a store, the memory area is checked to see if it has
# been changed.
0.31,6.RT,11.RA,16.RB,21.20,31./:X:::Load Word And Reserve Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*603: PPC_UNIT_LSU, PPC_UNIT_IU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_IU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
RESERVE = 1;
RESERVE_ADDR = real_addr(EA, 1/*is-read?*/);
RESERVE_DATA = MEM(unsigned, EA, 4);
*rT = RESERVE_DATA;
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.31,6.RT,11.RA,16.RB,21.84,31./:X:64::Load Doubleword And Reserve Indexed
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
RESERVE = 1;
RESERVE_ADDR = real_addr(EA, 1/*is-read?*/);
RESERVE_DATA = MEM(unsigned, EA, 8);
*rT = RESERVE_DATA;
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.31,6.RS,11.RA,16.RB,21.150,31.1:X:::Store Word Conditional Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 8, 8, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 8, 8, 0
*604: PPC_UNIT_BPU, PPC_UNIT_BPU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
if (RESERVE) {
if (RESERVE_ADDR == real_addr(EA, 0/*is-read?*/)
&& /*HACK*/ RESERVE_DATA == MEM(unsigned, EA, 4)) {
STORE(EA, 4, *rS);
CR_SET_XER_SO(0, cr_i_zero);
}
else {
/* ment to randomly to store, we never do! */
CR_SET_XER_SO(0, 0);
}
RESERVE = 0;
}
else {
CR_SET_XER_SO(0, 0);
}
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 1/*Rc*/);
0.31,6.RS,11.RA,16.RB,21.214,31.1:X:64::Store Doubleword Conditional Indexed
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
if (RESERVE) {
if (RESERVE_ADDR == real_addr(EA, 0/*is-read?*/)
&& /*HACK*/ RESERVE_DATA == MEM(unsigned, EA, 8)) {
STORE(EA, 8, *rS);
CR_SET_XER_SO(0, cr_i_zero);
}
else {
/* ment to randomly to store, we never do */
CR_SET_XER_SO(0, 0);
}
RESERVE = 0;
}
else {
CR_SET_XER_SO(0, 0);
}
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK | RS_BITMASK, 1/*Rc*/);
0.31,6./,9.L,11./,16./,21.598,31./:X::sync:Synchronize
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 1, 0
/* do nothing */
#
# I.3.3.9 Fixed-Point Arithmetic Instructions
#
0.14,6.RT,11.RA,16.SI:D:::Add Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (RA_is_0) *rT = EXTS(SI);
else *rT = *rA + EXTS(SI);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rT, (long)*rT));
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1), 0);
0.15,6.RT,11.RA,16.SI:D:::Add Immediate Shifted
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (RA_is_0) *rT = EXTS(SI) << 16;
else *rT = *rA + (EXTS(SI) << 16);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rT, (long)*rT));
PPC_INSN_INT(RT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.RT,11.RA,16.RB,21.OE,22.266,31.Rc:XO:::Add
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD(*rB);
ALU_END(*rT, 0/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21.OE,22.40,31.Rc:XO:::Subtract From
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD(*rB);
ALU_ADD(1);
ALU_END(*rT, 0/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.12,6.RT,11.RA,16.SI:D:::Add Immediate Carrying
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD(EXTS(SI));
ALU_END(*rT, 1/*CA*/, 0/*OE*/, 0/*Rc*/);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, 0/*Rc*/);
0.13,6.RT,11.RA,16.SI:D:::Add Immediate Carrying and Record
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD(EXTS(SI));
ALU_END(*rT, 1/*CA*/, 0/*OE*/, 1/*Rc*/);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, 1/*Rc*/);
0.8,6.RT,11.RA,16.SI:D:::Subtract From Immediate Carrying
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD(EXTS(SI));
ALU_ADD(1);
ALU_END(*rT, 1/*CA*/, 0/*OE*/, 0/*Rc*/);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, 0/*Rc*/);
0.31,6.RT,11.RA,16.RB,21.OE,22.10,31.Rc:XO:::Add Carrying
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD(*rB);
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21.OE,22.8,31.Rc:XO:::Subtract From Carrying
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
/* RT <- ~RA + RB + 1 === RT <- RB - RA */
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD(*rB);
ALU_ADD(1);
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21.OE,22.138,31.Rc:XO:::Add Extended
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD(*rB);
ALU_ADD_CA;
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21.OE,22.136,31.Rc:XO:::Subtract From Extended
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD(*rB);
ALU_ADD_CA;
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16./,21.OE,22.234,31.Rc:XO:::Add to Minus One Extended
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD_CA;
ALU_ADD(-1);
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, Rc);
0.31,6.RT,11.RA,16./,21.OE,22.232,31.Rc:XO:::Subtract From Minus One Extended
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD_CA;
ALU_ADD(-1);
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, Rc);
0.31,6.RT,11.RA,16./,21.OE,22.202,31.Rc:XO::addze:Add to Zero Extended
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_ADD_CA;
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, Rc);
0.31,6.RT,11.RA,16./,21.OE,22.200,31.Rc:XO:::Subtract from Zero Extended
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD_CA;
ALU_END(*rT, 1/*CA*/, OE, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, Rc);
0.31,6.RT,11.RA,16./,21.OE,22.104,31.Rc:XO:::Negate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
ALU_BEGIN(*rA);
ALU_NOT;
ALU_ADD(1);
ALU_END(*rT,0/*CA*/,OE,Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, Rc);
0.7,6.RT,11.RA,16.SI:D::mulli:Multiply Low Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 3, 3, 0
signed_word prod = *rA * EXTS(SI);
*rT = prod;
PPC_INSN_INT(RT_BITMASK, RA_BITMASK, 0/*Rc*/);
0.31,6.RT,11.RA,16.RB,21.OE,22.233,31.Rc:D:64::Multiply Low Doubleword
0.31,6.RT,11.RA,16.RB,21.OE,22.235,31.Rc:XO::mullw:Multiply Low Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 4, 4, 0
int64_t a = (int32_t)(*rA);
int64_t b = (int32_t)(*rB);
int64_t prod = a * b;
signed_word t = prod;
*rT = *rA * *rB;
if (t != prod && OE)
XER |= (xer_overflow | xer_summary_overflow);
CR0_COMPARE(t, 0, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21./,22.73,31.Rc:XO:64::Multiply High Doubleword
0.31,6.RT,11.RA,16.RB,21./,22.75,31.Rc:XO::mulhw:Multiply High Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 5, 5, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 4, 4, 0
int64_t a = (int32_t)(*rA);
int64_t b = (int32_t)(*rB);
int64_t prod = a * b;
signed_word t = EXTRACTED64(prod, 0, 31);
*rT = t;
CR0_COMPARE(t, 0, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21./,22.9,31.Rc:XO:64::Multiply High Doubleword Unsigned
0.31,6.RT,11.RA,16.RB,21./,22.11,31.Rc:XO::mulhwu:Multiply High Word Unsigned
*601: PPC_UNIT_IU, PPC_UNIT_IU, 10, 10, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 6, 6, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 6, 6, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 4, 4, 0
uint64_t a = (uint32_t)(*rA);
uint64_t b = (uint32_t)(*rB);
uint64_t prod = a * b;
signed_word t = EXTRACTED64(prod, 0, 31);
*rT = t;
CR0_COMPARE(t, 0, Rc);
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21.OE,22.489,31.Rc:XO:64::Divide Doubleword
0.31,6.RT,11.RA,16.RB,21.OE,22.491,31.Rc:XO::divw:Divide Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 36, 36, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 37, 37, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 37, 37, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 20, 20, 0
int64_t dividend = (int32_t)(*rA);
int64_t divisor = (int32_t)(*rB);
if (divisor == 0 /* nb 0x8000..0 is sign extended */
|| (dividend == 0x80000000 && divisor == -1)) {
if (OE)
XER |= (xer_overflow | xer_summary_overflow);
CR0_COMPARE(0, 0, Rc);
}
else {
int64_t quotent = dividend / divisor;
*rT = quotent;
CR0_COMPARE((signed_word)quotent, 0, Rc);
}
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
0.31,6.RT,11.RA,16.RB,21.OE,22.457,31.Rc:XO:64::Divide Doubleword Unsigned
0.31,6.RT,11.RA,16.RB,21.OE,22.459,31.Rc:XO::divwu:Divide Word Unsigned
*601: PPC_UNIT_IU, PPC_UNIT_IU, 36, 36, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 37, 37, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 37, 37, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 20, 20, 0
uint64_t dividend = (uint32_t)(*rA);
uint64_t divisor = (uint32_t)(*rB);
if (divisor == 0) {
if (OE)
XER |= (xer_overflow | xer_summary_overflow);
CR0_COMPARE(0, 0, Rc);
}
else {
uint64_t quotent = dividend / divisor;
*rT = quotent;
CR0_COMPARE((signed_word)quotent, 0, Rc);
}
PPC_INSN_INT(RT_BITMASK, RA_BITMASK | RB_BITMASK, Rc);
#
# I.3.3.10 Fixed-Point Compare Instructions
#
0.11,6.BF,9./,10.L,11.RA,16.SI:D:::Compare Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (!is_64bit_mode && L)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
signed_word a;
signed_word b = EXTS(SI);
if (L == 0)
a = EXTENDED(*rA);
else
a = *rA;
CR_COMPARE(BF, a, b);
}
PPC_INSN_INT_CR(0, RA_BITMASK, BF_BITMASK);
0.31,6.BF,9./,10.L,11.RA,16.RB,21.0,31./:X:::Compare
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (!is_64bit_mode && L)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
signed_word a;
signed_word b;
if (L == 0) {
a = EXTENDED(*rA);
b = EXTENDED(*rB);
}
else {
a = *rA;
b = *rB;
}
CR_COMPARE(BF, a, b);
}
PPC_INSN_INT_CR(0, RA_BITMASK | RB_BITMASK, BF_BITMASK);
0.10,6.BF,9./,10.L,11.RA,16.UI:D:::Compare Logical Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (!is_64bit_mode && L)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
unsigned_word a;
unsigned_word b = UI;
if (L == 0)
a = MASKED(*rA, 32, 63);
else
a = *rA;
CR_COMPARE(BF, a, b);
}
PPC_INSN_INT_CR(0, RA_BITMASK, BF_BITMASK);
0.31,6.BF,9./,10.L,11.RA,16.RB,21.32,31./:X:::Compare Logical
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
if (!is_64bit_mode && L)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
unsigned_word a;
unsigned_word b;
if (L == 0) {
a = MASKED(*rA, 32, 63);
b = MASKED(*rB, 32, 63);
}
else {
a = *rA;
b = *rB;
}
CR_COMPARE(BF, a, b);
}
PPC_INSN_INT_CR(0, RA_BITMASK | RB_BITMASK, BF_BITMASK);
#
# I.3.3.11 Fixed-Point Trap Instructions
#
0.2,6.TO,11.RA,16.SI:D:64::Trap Doubleword Immediate
if (!is_64bit_mode)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
signed_word a = *rA;
signed_word b = EXTS(SI);
if ((a < b && TO{0})
|| (a > b && TO{1})
|| (a == b && TO{2})
|| ((unsigned_word)a < (unsigned_word)b && TO{3})
|| ((unsigned_word)a > (unsigned_word)b && TO{4})
)
program_interrupt(processor, cia,
trap_program_interrupt);
}
0.3,6.TO,11.RA,16.SI:D:::Trap Word Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
signed_word a = EXTENDED(*rA);
signed_word b = EXTS(SI);
if ((a < b && TO{0})
|| (a > b && TO{1})
|| (a == b && TO{2})
|| ((unsigned_word)a < (unsigned_word)b && TO{3})
|| ((unsigned_word)a > (unsigned_word)b && TO{4})
)
program_interrupt(processor, cia,
trap_program_interrupt);
0.31,6.TO,11.RA,16.RB,21.68,31./:X:64::Trap Doubleword
if (!is_64bit_mode)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
signed_word a = *rA;
signed_word b = *rB;
if ((a < b && TO{0})
|| (a > b && TO{1})
|| (a == b && TO{2})
|| ((unsigned_word)a < (unsigned_word)b && TO{3})
|| ((unsigned_word)a > (unsigned_word)b && TO{4})
)
program_interrupt(processor, cia,
trap_program_interrupt);
}
0.31,6.TO,11.RA,16.RB,21.4,31./:X:::Trap Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
signed_word a = EXTENDED(*rA);
signed_word b = EXTENDED(*rB);
if (TO == 12 && rA == rB) {
ITRACE(trace_breakpoint, ("breakpoint\n"));
cpu_halt(processor, cia, was_trap, 0);
}
else if ((a < b && TO{0})
|| (a > b && TO{1})
|| (a == b && TO{2})
|| ((unsigned_word)a < (unsigned_word)b && TO{3})
|| ((unsigned_word)a > (unsigned_word)b && TO{4})
)
program_interrupt(processor, cia,
trap_program_interrupt);
#
# I.3.3.12 Fixed-Point Logical Instructions
#
0.28,6.RS,11.RA,16.UI:D:::AND Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS & UI;
CR0_COMPARE(*rA, 0, 1/*Rc*/);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, 1/*Rc*/);
0.29,6.RS,11.RA,16.UI:D:::AND Immediate Shifted
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS & (UI << 16);
CR0_COMPARE(*rA, 0, 1/*Rc*/);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, 1/*Rc*/);
0.24,6.RS,11.RA,16.UI:D:::OR Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS | UI;
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, 0/*Rc*/);
0.25,6.RS,11.RA,16.UI:D:::OR Immediate Shifted
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS | (UI << 16);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, 0/*Rc*/);
0.26,6.RS,11.RA,16.UI:D:::XOR Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS ^ UI;
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, 0/*Rc*/);
0.27,6.RS,11.RA,16.UI:D:::XOR Immediate Shifted
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS ^ (UI << 16);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, 0/*Rc*/);
0.31,6.RS,11.RA,16.RB,21.28,31.Rc:X:::AND
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS & *rB;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.444,31.Rc:X:::OR
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS | *rB;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.316,31.Rc:X:::XOR
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS ^ *rB;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.476,31.Rc:X:::NAND
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = ~(*rS & *rB);
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.124,31.Rc:X:::NOR
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = ~(*rS | *rB);
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.284,31.Rc:X:::Equivalent
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = ~(*rS ^ *rB); /* A === B */
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.60,31.Rc:X:::AND with Complement
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS & ~*rB;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.412,31.Rc:X:::OR with Complement
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = *rS | ~*rB;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK | RB_BITMASK, Rc);
0.31,6.RS,11.RA,16./,21.954,31.Rc:X::extsb:Extend Sign Byte
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = (signed_word)(int8_t)*rS;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.31,6.RS,11.RA,16./,21.922,31.Rc:X::extsh:Extend Sign Half Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
*rA = (signed_word)(int16_t)*rS;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.31,6.RS,11.RA,16./,21.986,31.Rc:X:64::Extend Sign Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
# *rA = (signed_word)(int32_t)*rS;
# CR0_COMPARE(*rA, 0, Rc);
0.31,6.RS,11.RA,16./,21.58,31.Rc:X:64::Count Leading Zeros Doubleword
# int count = 0;
# uint64_t mask = BIT64(0);
# uint64_t source = *rS;
# while (!(source & mask) && mask != 0) {
# mask >>= 1;
# count++;
# }
# *rA = count;
# CR0_COMPARE(count, 0, Rc); /* FIXME - is this correct */
0.31,6.RS,11.RA,16./,21.26,31.Rc:X:::Count Leading Zeros Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
int count = 0;
uint32_t mask = BIT32(0);
uint32_t source = *rS;
while (!(source & mask) && mask != 0) {
mask >>= 1;
count++;
}
*rA = count;
ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
CR0_COMPARE(count, 0, Rc); /* FIXME - is this correct */
#
# I.3.3.13 Fixed-Point Rotate and Shift Instructions
#
0.30,6.RS,11.RA,16.sh_0_4,21.mb,27.0,30.sh_5,31.Rc:MD:64::Rotate Left Doubleword Immediate then Clear Left
# long n = (sh_5 << 4) | sh_0_4;
# unsigned_word r = ROTL64(*rS, n);
# long b = (mb_5 << 4) | mb_0_4;
# unsigned_word m = MASK(b, 63);
# signed_word result = r & m;
# *rA = result;
# ITRACE(trace_alu, (" Result = %ld (0x%lx)\n", (long)*rA, (long)*rA));
# CR0_COMPARE(result, 0, Rc); /* FIXME - is this correct */
0.30,6.RS,11.RA,16.sh_0_4,21.me,27.1,30.sh_5,31.Rc:MD:64::Rotate Left Doubleword Immediate then Clear Right
# long n = (sh_5 << 4) | sh_0_4;
# unsigned_word r = ROTL64(*rS, n);
# long e = (me_5 << 4) | me_0_4;
# unsigned_word m = MASK(0, e);
# signed_word result = r & m;
# *rA = result;
# CR0_COMPARE(result, 0, Rc); /* FIXME - is this correct */
0.30,6.RS,11.RA,16.sh_0_4,21.mb,27.2,30.sh_5,31.Rc:MD:64::Rotate Left Doubleword Immediate then Clear
# long n = (sh_5 << 4) | sh_0_4;
# unsigned_word r = ROTL64(*rS, n);
# long b = (mb_5 << 4) | mb_0_4;
# unsigned_word m = MASK(0, (64-n));
# signed_word result = r & m;
# *rA = result;
# CR0_COMPARE(result, 0, Rc); /* FIXME - is this correct */
0.21,6.RS,11.RA,16.SH,21.MB,26.ME,31.Rc:M:::Rotate Left Word Immediate then AND with Mask
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
long n = SH;
uint32_t s = *rS;
uint32_t r = ROTL32(s, n);
uint32_t m = MASK(MB+32, ME+32);
signed_word result = r & m;
*rA = result;
CR0_COMPARE(result, 0, Rc);
ITRACE(trace_alu,
("n=%ld, s=0x%lx, r=0x%lx, m=0x%lx, result=0x%lx, cr=0x%lx\n",
n, (unsigned long)s, (unsigned long)r, (unsigned long)m,
(unsigned long)result, (unsigned long)CR));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.30,6.RS,11.RA,16.RB,21.mb,27.8,31.Rc:MDS:64::Rotate Left Doubleword then Clear Left
# long n = MASKED(*rB, 58, 63);
# unsigned_word r = ROTL64(*rS, n);
# long b = (mb_5 << 4) | mb_0_4;
# unsigned_word m = MASK(b, 63);
# signed_word result = r & m;
# *rA = result;
# CR0_COMPARE(result, 0, Rc);
0.30,6.RS,11.RA,16.RB,21.me,27.9,31.Rc:MDS:64::Rotate Left Doubleword then Clear Right
# long n = MASKED(*rB, 58, 63);
# unsigned_word r = ROTL64(*rS, n);
# long e = (me_5 << 4) | me_0_4;
# unsigned_word m = MASK(0, e);
# signed_word result = r & m;
# *rA = result;
# CR0_COMPARE(result, 0, Rc);
0.23,6.RS,11.RA,16.RB,21.MB,26.ME,31.Rc:M:::Rotate Left Word then AND with Mask
long n = MASKED(*rB, 59, 63);
uint32_t r = ROTL32(*rS, n);
uint32_t m = MASK(MB+32, ME+32);
signed_word result = r & m;
*rA = result;
CR0_COMPARE(result, 0, Rc);
0.30,6.RS,11.RA,16.sh_0_4,21.mb,27.3,30.sh_5,31.Rc:MD:64::Rotate Left Doubleword Immediate then Mask Insert
# long n = (sh_5 << 4) | sh_0_4;
# unsigned_word r = ROTL64(*rS, n);
# long b = (mb_5 << 4) | mb_0_4;
# unsigned_word m = MASK(b, (64-n));
# signed_word result = (r & m) | (*rA & ~m)
# *rA = result;
# CR0_COMPARE(result, 0, Rc);
0.20,6.RS,11.RA,16.SH,21.MB,26.ME,31.Rc:M::rlwimi:Rotate Left Word Immediate then Mask Insert
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
long n = SH;
uint32_t r = ROTL32(*rS, n);
uint32_t m = MASK(MB+32, ME+32);
signed_word result = (r & m) | (*rA & ~m);
*rA = result;
ITRACE(trace_alu, (": n=%ld *rS=0x%lx r=0x%lx m=0x%lx result=0x%lx\n",
n, (unsigned long)*rS, (unsigned long)r, (unsigned long)m,
(unsigned long)result));
CR0_COMPARE(result, 0, Rc);
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.27,31.Rc:X:64::Shift Left Doubleword
0.31,6.RS,11.RA,16.RB,21.24,31.Rc:X:::Shift Left Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
int n = MASKED(*rB, 58, 63);
uint32_t source = *rS;
signed_word shifted;
if (n < 32)
shifted = (source << n);
else
shifted = 0;
*rA = shifted;
CR0_COMPARE(shifted, 0, Rc);
ITRACE(trace_alu,
("n=%d, source=0x%lx, shifted=0x%lx\n",
n, (unsigned long)source, (unsigned long)shifted));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.539,31.Rc:X:64::Shift Right Doubleword
0.31,6.RS,11.RA,16.RB,21.536,31.Rc:X:::Shift Right Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
int n = MASKED(*rB, 58, 63);
uint32_t source = *rS;
signed_word shifted;
if (n < 32)
shifted = (source >> n);
else
shifted = 0;
*rA = shifted;
CR0_COMPARE(shifted, 0, Rc);
ITRACE(trace_alu, \
("n=%d, source=0x%lx, shifted=0x%lx\n",
n, (unsigned long)source, (unsigned long)shifted));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.31,6.RS,11.RA,16.sh_0_4,21.413,30.sh_5,31.Rc:XS:64::Shift Right Algebraic Doubleword Immediate
0.31,6.RS,11.RA,16.SH,21.824,31.Rc:X:::Shift Right Algebraic Word Immediate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
int n = SH;
signed_word r = ROTL32(*rS, /*64*/32-n);
signed_word m = MASK(n+32, 63);
int S = MASKED(*rS, 32, 32);
signed_word shifted = (r & m) | (S ? ~m : 0);
*rA = shifted;
if (S && ((r & ~m) & MASK(32, 63)) != 0)
XER |= xer_carry;
else
XER &= ~xer_carry;
CR0_COMPARE(shifted, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx), XER = %ld\n",
(long)*rA, (long)*rA, (long)XER));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
0.31,6.RS,11.RA,16.RB,21.794,31.Rc:X:64::Shift Right Algebraic Doubleword
0.31,6.RS,11.RA,16.RB,21.792,31.Rc:X:::Shift Right Algebraic Word
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603e:PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*604: PPC_UNIT_SCIU1, PPC_UNIT_SCIU2, 1, 1, 0
uint64_t mask;
int n = MASKED(*rB, 59, 63);
int32_t source = (int32_t)*rS; /* signed to keep sign bit */
int S = (MASKED(*rS,32,32) != 0);
int64_t r = ((uint64_t) source);
r = ((uint64_t) source) << 32 | (uint32_t) source;
r = ROTL64(r,64-n);
if (MASKED(*rB,58,58) == 0)
mask = (uint64_t) MASK64(n+32,63);
else
mask = (uint64_t) 0;
*rA = (signed_word) ((r & mask) | (((int64_t) -1*S) & ~mask)); /* if 64bit will sign extend */
if (S && (MASKED(r & ~mask,32,63)!=0))
XER |= xer_carry;
else
XER &= ~xer_carry;
CR0_COMPARE(*rA, 0, Rc);
ITRACE(trace_alu, (" Result = %ld (0x%lx), XER = %ld\n",
(long)*rA, (long)*rA, (long)XER));
PPC_INSN_INT(RA_BITMASK, RS_BITMASK, Rc);
#
# I.3.3.14 Move to/from System Register Instructions
#
0.31,6.RS,11.SPR,21.467,31./:XFX::mtspr %SPR, %RS:Move to Special Purpose Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
int n = (SPR{5:9} << 5) | SPR{0:4};
if (SPR{0} && IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else if (!spr_is_valid(n)
|| spr_is_readonly(n))
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
spreg new_val = (spr_length(n) == 64
? *rS
: MASKED(*rS, 32, 63));
/* HACK - time base registers need to be updated immediately */
if (WITH_TIME_BASE) {
switch (n) {
case spr_tbu:
cpu_set_time_base(processor,
(MASKED64(cpu_get_time_base(processor), 32, 63)
| INSERTED64(new_val, 0, 31)));
break;
case spr_tbl:
cpu_set_time_base(processor,
(MASKED64(cpu_get_time_base(processor), 0, 31)
| INSERTED64(new_val, 32, 63)));
break;
case spr_dec:
cpu_set_decrementer(processor, new_val);
break;
default:
SPREG(n) = new_val;
break;
}
}
else {
SPREG(n) = new_val;
}
}
PPC_INSN_TO_SPR(RS_BITMASK, n);
0.31,6.RT,11.SPR,21.339,31./:XFX::mfspr %RT, %SPR:Move from Special Purpose Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 3, 3, 0
int n = (SPR{5:9} << 5) | SPR{0:4};
if (SPR{0} && IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else if (!spr_is_valid(n))
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
else {
/* HACK - time base registers need to be calculated */
if (WITH_TIME_BASE) {
switch (n) {
case spr_dec:
*rT = cpu_get_decrementer(processor);
break;
case spr_tbrl:
if (is_64bit_implementation) *rT = TB;
else *rT = EXTRACTED64(TB, 32, 63);
break;
case spr_tbru:
if (is_64bit_implementation) *rT = EXTRACTED64(TB, 0, 31);
else *rT = EXTRACTED64(TB, 0, 31);
break;
case spr_tbu:
case spr_tbl:
/* NOTE - these SPR's are not readable. Use mftb[ul] */
default:
*rT = SPREG(n);
break;
}
}
else {
*rT = SPREG(n);
}
}
PPC_INSN_FROM_SPR(RT_BITMASK, n);
0.31,6.RS,11./,12.FXM,20./,21.144,31./:XFX::mtfcr:Move to Condition Register Fields
*601: PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
if (FXM == 0xff) {
CR = *rS;
}
else {
unsigned_word mask = 0;
unsigned_word f;
for (f = 0; f < 8; f++) {
if (FXM & (0x80 >> f))
mask |= (0xf << 4*(7-f));
}
CR = (MASKED(*rS, 32, 63) & mask) | (CR & ~mask);
}
PPC_INSN_MTCR(RS_BITMASK, FXM);
0.31,6.BF,9./,11./,16./,21.512,31./:X:::Move to Condition Register from XER
# CR_SET(BF, EXTRACTED32(XER, 0, 3));
# MBLIT32(XER, 0, 3, 0);
0.31,6.RT,11./,16./,21.19,31./:X:::Move From Condition Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 3, 3, 0
*rT = (uint32_t)CR;
PPC_INSN_MFCR(RT_BITMASK);
#
# I.4.6.2 Floating-Point Load Instructions
#
0.48,6.FRT,11.RA,16.D:D:f:lfs:Load Floating-Point Single
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
*frT = DOUBLE(MEM(unsigned, EA, 4));
PPC_INSN_INT_FLOAT(0, FRT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.FRT,11.RA,16.RB,21.535,31./:X:f::Load Floating-Point Single Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*frT = DOUBLE(MEM(unsigned, EA, 4));
PPC_INSN_INT_FLOAT(0, FRT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.49,6.FRT,11.RA,16.D:D:f::Load Floating-Point Single with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
*frT = DOUBLE(MEM(unsigned, EA, 4));
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, FRT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.FRT,11.RA,16.RB,21.567,31./:X:f::Load Floating-Point Single with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
*frT = DOUBLE(MEM(unsigned, EA, 4));
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, FRT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.50,6.FRT,11.RA,16.D:D:f::Load Floating-Point Double
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
*frT = MEM(unsigned, EA, 8);
PPC_INSN_INT_FLOAT(0, FRT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.FRT,11.RA,16.RB,21.599,31./:X:f::Load Floating-Point Double Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
*frT = MEM(unsigned, EA, 8);
PPC_INSN_INT_FLOAT(0, FRT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.51,6.FRT,11.RA,16.D:D:f::Load Floating-Point Double with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
*frT = MEM(unsigned, EA, 8);
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, FRT_BITMASK, (RA_BITMASK & ~1), 0);
0.31,6.FRT,11.RA,16.RB,21.631,31./:X:f::Load Floating-Point Double with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 3, 3, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
*frT = MEM(unsigned, EA, 8);
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, FRT_BITMASK, (RA_BITMASK & ~1) | RB_BITMASK, 0);
#
# I.4.6.3 Floating-Point Store Instructions
#
0.52,6.FRS,11.RA,16.D:D:f::Store Floating-Point Single
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
STORE(EA, 4, SINGLE(*frS));
PPC_INSN_INT_FLOAT(0, 0, (RA_BITMASK & ~1), FRS_BITMASK);
0.31,6.FRS,11.RA,16.RB,21.663,31./:X:f::Store Floating-Point Single Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 4, SINGLE(*frS));
PPC_INSN_INT_FLOAT(0, 0, (RA_BITMASK & ~1) | RB_BITMASK, FRS_BITMASK);
0.53,6.FRS,11.RA,16.D:D:f::Store Floating-Point Single with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
STORE(EA, 4, SINGLE(*frS));
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, 0, (RA_BITMASK & ~1), FRS_BITMASK);
0.31,6.FRS,11.RA,16.RB,21.695,31./:X:f::Store Floating-Point Single with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
STORE(EA, 4, SINGLE(*frS));
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, 0, (RA_BITMASK & ~1) | RB_BITMASK, FRS_BITMASK);
0.54,6.FRS,11.RA,16.D:D:f::Store Floating-Point Double
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + EXTS(D);
STORE(EA, 8, *frS);
PPC_INSN_INT_FLOAT(0, 0, (RA_BITMASK & ~1), FRS_BITMASK);
0.31,6.FRS,11.RA,16.RB,21.727,31./:X:f::Store Floating-Point Double Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 8, *frS);
PPC_INSN_INT_FLOAT(0, 0, (RA_BITMASK & ~1) | RB_BITMASK, FRS_BITMASK);
0.31,6.FRS,11.RA,16.RB,21.983,31./:X:f::Store Floating-Point Integer Word Indexed
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
STORE(EA, 4, *frS);
PPC_INSN_INT_FLOAT(0, 0, (RA_BITMASK & ~1) | RB_BITMASK, FRS_BITMASK);
0.55,6.FRS,11.RA,16.D:D:f::Store Floating-Point Double with Update
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + EXTS(D);
STORE(EA, 8, *frS);
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, 0, (RA_BITMASK & ~1), FRS_BITMASK);
0.31,6.FRS,11.RA,16.RB,21.759,31./:X:f::Store Floating-Point Double with Update Indexed
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
unsigned_word EA;
if (RA_is_0)
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
EA = *rA + *rB;
STORE(EA, 8, *frS);
*rA = EA;
PPC_INSN_INT_FLOAT(RA_BITMASK, 0, (RA_BITMASK & ~1) | RB_BITMASK, FRS_BITMASK);
#
# I.4.6.4 Floating-Point Move Instructions
#
0.63,6.FRT,11./,16.FRB,21.72,31.Rc:X:f::Floating Move Register
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*frT = *frB;
CR1_UPDATE(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
0.63,6.FRT,11./,16.FRB,21.40,31.Rc:X:f::Floating Negate
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*frT = *frB ^ BIT64(0);
CR1_UPDATE(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
0.63,6.FRT,11./,16.FRB,21.264,31.Rc:X:f::Floating Absolute Value
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*frT = *frB & ~BIT64(0);
CR1_UPDATE(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
0.63,6.FRT,11./,16.FRB,21.136,31.Rc:X:f::Floating Negative Absolute Value
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*frT = *frB | BIT64(0);
CR1_UPDATE(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
#
# I.4.6.5 Floating-Point Arithmetic Instructions
#
0.63,6.FRT,11.FRA,16.FRB,21./,26.21,31.Rc:A:f:fadd:Floating Add
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frB,
fpscr_vxsnan | fpscr_vxisi,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = *(double*)frA + *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21./,26.21,31.Rc:A:f:fadds:Floating Add Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frB,
fpscr_vxsnan | fpscr_vxisi,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
1); /*single-precision*/
}
else {
/*HACK!*/
float s = *(double*)frA + *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK, Rc);
0.63,6.FRT,11.FRA,16.FRB,21./,26.20,31.Rc:A:f:fsub:Floating Subtract
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frB,
fpscr_vxsnan | fpscr_vxisi,
0, /*single?*/
1) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = *(double*)frA - *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21./,26.20,31.Rc:A:f:fsubs:Floating Subtract Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frB,
fpscr_vxsnan | fpscr_vxisi,
1, /*single?*/
1) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
1); /*single-precision*/
}
else {
/*HACK!*/
float s = *(double*)frA - *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK, Rc);
0.63,6.FRT,11.FRA,16./,21.FRC,26.25,31.Rc:A:f:fmul:Floating Multiply
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 5, 5, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = *(double*)frA * *(double*)frC;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRC_BITMASK, Rc);
0.59,6.FRT,11.FRA,16./,21.FRC,26.25,31.Rc:A:f:fmuls:Floating Multiply Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
1); /*single-precision*/
}
else {
/*HACK!*/
float s = *(double*)frA * *(double*)frC;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRC_BITMASK, Rc);
0.63,6.FRT,11.FRA,16.FRB,21./,26.18,31.Rc:A:f:fdiv:Floating Divide
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 31, 31, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 33, 33, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 33, 33, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 32, 32, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frB,
fpscr_vxsnan | fpscr_vxzdz,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else if (is_invalid_zero_divide (processor, cia,
*frA, *frB,
0 /*single?*/)) {
invalid_zero_divide_operation (processor, cia,
frT, *frA, *frB,
0 /*single?*/);
}
else {
/*HACK!*/
double s = *(double*)frA / *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21./,26.18,31.Rc:A:f:fdivs:Floating Divide Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 17, 17, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 18, 18, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 18, 18, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 18, 18, 0
FPSCR_BEGIN;
if (is_invalid_operation(processor, cia,
*frA, *frB,
fpscr_vxsnan | fpscr_vxzdz,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, *frA, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
1); /*single-precision*/
}
else if (is_invalid_zero_divide (processor, cia,
*frA, *frB,
1 /*single?*/)) {
invalid_zero_divide_operation (processor, cia,
frT, *frA, *frB,
1 /*single?*/);
}
else {
/*HACK!*/
float s = *(double*)frA / *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK, Rc);
0.63,6.FRT,11.FRA,16.FRB,21.FRC,26.29,31.Rc:A:f:fmadd:Floating Multiply-Add
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 5, 5, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
double product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
0, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the add */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = product + *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21.FRC,26.29,31.Rc:A:f::Floating Multiply-Add Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
float product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
1, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the add */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
float s = product + *(double*)frB;
*(double*)frT = (double)s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.63,6.FRT,11.FRA,16.FRB,21.FRC,26.28,31.Rc:A:f::Floating Multiply-Subtract
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 5, 5, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
double product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
0, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the subtract */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = product - *(double*)frB;
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21.FRC,26.28,31.Rc:A:f::Floating Multiply-Subtract Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
float product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
1, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the subtract */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
float s = product - *(double*)frB;
*(double*)frT = (double)s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.63,6.FRT,11.FRA,16.FRB,21.FRC,26.31,31.Rc:A:f::Floating Negative Multiply-Add
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 5, 5, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
double product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
0, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the add */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = -(product + *(double*)frB);
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21.FRC,26.31,31.Rc:A:f::Floating Negative Multiply-Add Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
float product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
1, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the add */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
float s = -(product + *(double*)frB);
*(double*)frT = (double)s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.63,6.FRT,11.FRA,16.FRB,21.FRC,26.30,31.Rc:A:f::Floating Negative Multiply-Subtract
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 5, 5, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 2, 4, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
double product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
0, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the subtract */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
0, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
double s = -(product - *(double*)frB);
*(double*)frT = s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
0.59,6.FRT,11.FRA,16.FRB,21.FRC,26.30,31.Rc:A:f::Floating Negative Multiply-Subtract Single
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
float product; /*HACK! - incorrectly loosing precision ... */
/* compute the multiply */
if (is_invalid_operation(processor, cia,
*frA, *frC,
fpscr_vxsnan | fpscr_vximz,
1, /*single?*/
0) /*negate?*/) {
union { double d; uint64_t u; } tmp;
invalid_arithemetic_operation(processor, cia,
&tmp.u, *frA, 0, *frC,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
product = tmp.d;
}
else {
/*HACK!*/
product = *(double*)frA * *(double*)frC;
}
/* compute the subtract */
if (is_invalid_operation(processor, cia,
product, *frB,
fpscr_vxsnan | fpscr_vxisi,
1, /*single?*/
0) /*negate?*/) {
invalid_arithemetic_operation(processor, cia,
frT, product, *frB, 0,
0, /*instruction_is_frsp*/
0, /*instruction_is_convert_to_64bit*/
0, /*instruction_is_convert_to_32bit*/
0); /*single-precision*/
}
else {
/*HACK!*/
float s = -(product - *(double*)frB);
*(double*)frT = (double)s;
}
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
#
# I.4.6.6 Floating-Point Rounding and Conversion Instructions
#
0.63,6.FRT,11./,16.FRB,21.12,31.Rc:X:f::Floating Round to Single-Precision
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
int sign;
int exp;
uint64_t frac_grx;
/***/
/* split off cases for what to do */
if (EXTRACTED64(*frB, 1, 11) < 897
&& EXTRACTED64(*frB, 1, 63) > 0) {
if ((FPSCR & fpscr_ue) == 0) GOTO(Disabled_Exponent_Underflow);
if ((FPSCR & fpscr_ue) != 0) GOTO(Enabled_Exponent_Underflow);
}
if (EXTRACTED64(*frB, 1, 11) > 1150
&& EXTRACTED64(*frB, 1, 11) < 2047) {
if ((FPSCR & fpscr_oe) == 0) GOTO(Disabled_Exponent_Overflow);
if ((FPSCR & fpscr_oe) != 0) GOTO(Enabled_Exponent_Overflow);
}
if (EXTRACTED64(*frB, 1, 11) > 896
&& EXTRACTED64(*frB, 1, 11) < 1151) GOTO(Normal_Operand);
if (EXTRACTED64(*frB, 1, 63) == 0) GOTO(Zero_Operand);
if (EXTRACTED64(*frB, 1, 11) == 2047) {
if (EXTRACTED64(*frB, 12, 63) == 0) GOTO(Infinity_Operand);
if (EXTRACTED64(*frB, 12, 12) == 1) GOTO(QNaN_Operand);
if (EXTRACTED64(*frB, 12, 12) == 0
&& EXTRACTED64(*frB, 13, 63) > 0) GOTO(SNaN_Operand);
}
/**/
LABEL(Disabled_Exponent_Underflow):
sign = EXTRACTED64(*frB, 0, 0);
if (EXTRACTED64(*frB, 1, 11) == 0) {
exp = -1022;
frac_grx = INSERTED64(EXTRACTED64(*frB, 12, 63), 1, 52);
}
if (EXTRACTED64(*frB, 1, 11) > 0) {
exp = EXTRACTED64(*frB, 1, 11) - 1023;
frac_grx = BIT64(0) | INSERTED64(EXTRACTED64(*frB, 12, 63), 1, 52);
}
/* G|R|X == zero from above */
while (exp < -126) {
exp = exp + 1;
frac_grx = (INSERTED64(EXTRACTED64(frac_grx, 0, 54), 1, 55)
| MASKED64(frac_grx, 55, 55));
}
FPSCR_SET_UX(EXTRACTED64(frac_grx, 24, 55) > 0);
Round_Single(processor, sign, &exp, &frac_grx);
FPSCR_SET_XX(FPSCR & fpscr_fi);
if (EXTRACTED64(frac_grx, 0, 52) == 0) {
*frT = INSERTED64(sign, 0, 0);
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_zero);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_neg_zero);
}
if (EXTRACTED64(frac_grx, 0, 52) > 0) {
if (EXTRACTED64(frac_grx, 0, 0) == 1) {
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_neg_normal_number);
}
if (EXTRACTED64(frac_grx, 0, 0) == 0) {
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_denormalized_number);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_neg_denormalized_number);
}
/*Normalize_Operand:*/
while (EXTRACTED64(frac_grx, 0, 0) == 0) {
exp = exp - 1;
frac_grx = INSERTED64(EXTRACTED64(frac_grx, 1, 52), 0, 51);
}
*frT = (INSERTED64(sign, 0, 0)
| INSERTED64(exp + 1023, 1, 11)
| INSERTED64(EXTRACTED64(frac_grx, 1, 52), 12, 63));
}
GOTO(Done);
/**/
LABEL(Enabled_Exponent_Underflow):
FPSCR_SET_UX(1);
sign = EXTRACTED64(*frB, 0, 0);
if (EXTRACTED64(*frB, 1, 11) == 0) {
exp = -1022;
frac_grx = INSERTED64(EXTRACTED64(*frB, 12, 63), 1, 52);
}
if (EXTRACTED64(*frB, 1, 11) > 0) {
exp = EXTRACTED64(*frB, 1, 11) - 1023;
frac_grx = (BIT64(0) |
INSERTED64(EXTRACTED64(*frB, 12, 63), 1, 52));
}
/*Normalize_Operand:*/
while (EXTRACTED64(frac_grx, 0, 0) == 0) {
exp = exp - 1;
frac_grx = INSERTED64(EXTRACTED64(frac_grx, 1, 52), 0, 51);
}
Round_Single(processor, sign, &exp, &frac_grx);
FPSCR_SET_XX(FPSCR & fpscr_fi);
exp = exp + 192;
*frT = (INSERTED64(sign, 0, 0)
| INSERTED64(exp + 1023, 1, 11)
| INSERTED64(EXTRACTED64(frac_grx, 1, 52), 12, 63));
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_neg_normal_number);
GOTO(Done);
/**/
LABEL(Disabled_Exponent_Overflow):
FPSCR_SET_OX(1);
if ((FPSCR & fpscr_rn) == fpscr_rn_round_to_nearest) {
if (EXTRACTED64(*frB, 0, 0) == 0) {
*frT = INSERTED64(0x7FF00000, 0, 31) | 0x00000000;
FPSCR_SET_FPRF(fpscr_rf_pos_infinity);
}
if (EXTRACTED64(*frB, 0, 0) == 1) {
*frT = INSERTED64(0xFFF00000, 0, 31) | 0x00000000;
FPSCR_SET_FPRF(fpscr_rf_neg_infinity);
}
}
if ((FPSCR & fpscr_rn) == fpscr_rn_round_towards_zero) {
if (EXTRACTED64(*frB, 0, 0) == 0) {
*frT = INSERTED64(0x47EFFFFF, 0, 31) | 0xE0000000;
FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
}
if (EXTRACTED64(*frB, 0, 0) == 1) {
*frT = INSERTED64(0xC7EFFFFF, 0, 31) | 0xE0000000;
FPSCR_SET_FPRF(fpscr_rf_neg_normal_number);
}
}
if ((FPSCR & fpscr_rn) == fpscr_rn_round_towards_pos_infinity) {
if (EXTRACTED64(*frB, 0, 0) == 0) {
*frT = INSERTED64(0x7FF00000, 0, 31) | 0x00000000;
FPSCR_SET_FPRF(fpscr_rf_pos_infinity);
}
if (EXTRACTED64(*frB, 0, 0) == 1) {
*frT = INSERTED64(0xC7EFFFFF, 0, 31) | 0xE0000000;
FPSCR_SET_FPRF(fpscr_rf_neg_normal_number);
}
}
if ((FPSCR & fpscr_rn) == fpscr_rn_round_towards_neg_infinity) {
if (EXTRACTED64(*frB, 0, 0) == 0) {
*frT = INSERTED64(0x47EFFFFF, 0, 31) | 0xE0000000;
FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
}
if (EXTRACTED64(*frB, 0, 0) == 1) {
*frT = INSERTED64(0xFFF00000, 0, 31) | 0x00000000;
FPSCR_SET_FPRF(fpscr_rf_neg_infinity);
}
}
/* FPSCR[FR] <- undefined */
FPSCR_SET_FI(1);
FPSCR_SET_XX(1);
GOTO(Done);
/**/
LABEL(Enabled_Exponent_Overflow):
sign = EXTRACTED64(*frB, 0, 0);
exp = EXTRACTED64(*frB, 1, 11) - 1023;
frac_grx = BIT64(0) | INSERTED64(EXTRACTED64(*frB, 12, 63), 1, 52);
Round_Single(processor, sign, &exp, &frac_grx);
FPSCR_SET_XX(FPSCR & fpscr_fi);
/**/
LABEL(Enabled_Overflow):
FPSCR_SET_OX(1);
exp = exp - 192;
*frT = (INSERTED64(sign, 0, 0)
| INSERTED64(exp + 1023, 1, 11)
| INSERTED64(EXTRACTED64(frac_grx, 1, 52), 12, 63));
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_neg_normal_number);
GOTO(Done);
/**/
LABEL(Zero_Operand):
*frT = *frB;
if (EXTRACTED64(*frB, 0, 0) == 0) FPSCR_SET_FPRF(fpscr_rf_pos_zero);
if (EXTRACTED64(*frB, 0, 0) == 1) FPSCR_SET_FPRF(fpscr_rf_neg_zero);
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
GOTO(Done);
/**/
LABEL(Infinity_Operand):
*frT = *frB;
if (EXTRACTED64(*frB, 0, 0) == 0) FPSCR_SET_FPRF(fpscr_rf_pos_infinity);
if (EXTRACTED64(*frB, 0, 0) == 1) FPSCR_SET_FPRF(fpscr_rf_neg_infinity);
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
GOTO(Done);
/**/
LABEL(QNaN_Operand):
*frT = INSERTED64(EXTRACTED64(*frB, 0, 34), 0, 34);
FPSCR_SET_FPRF(fpscr_rf_quiet_nan);
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
GOTO(Done);
/**/
LABEL(SNaN_Operand):
FPSCR_OR_VX(fpscr_vxsnan);
if ((FPSCR & fpscr_ve) == 0) {
*frT = (MASKED64(*frB, 0, 11)
| BIT64(12)
| MASKED64(*frB, 13, 34));
FPSCR_SET_FPRF(fpscr_rf_quiet_nan);
}
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
GOTO(Done);
/**/
LABEL(Normal_Operand):
sign = EXTRACTED64(*frB, 0, 0);
exp = EXTRACTED64(*frB, 1, 11) - 1023;
frac_grx = BIT64(0) | INSERTED64(EXTRACTED64(*frB, 12, 63), 1, 52);
Round_Single(processor, sign, &exp, &frac_grx);
FPSCR_SET_XX(FPSCR & fpscr_fi);
if (exp > 127 && (FPSCR & fpscr_oe) == 0) GOTO(Disabled_Exponent_Overflow);
if (exp > 127 && (FPSCR & fpscr_oe) != 0) GOTO(Enabled_Overflow);
*frT = (INSERTED64(sign, 0, 0)
| INSERTED64(exp + 1023, 1, 11)
| INSERTED64(EXTRACTED64(frac_grx, 1, 52), 12, 63));
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_neg_normal_number);
GOTO(Done);
/**/
LABEL(Done):
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
0.63,6.FRT,11./,16.FRB,21.814,31.Rc:X:64,f::Floating Convert To Integer Doubleword
floating_point_assist_interrupt(processor, cia);
0.63,6.FRT,11./,16.FRB,21.815,31.Rc:X:64,f::Floating Convert To Integer Doubleword with round towards Zero
floating_point_assist_interrupt(processor, cia);
0.63,6.FRT,11./,16.FRB,21.14,31.Rc:X:f::Floating Convert To Integer Word
floating_point_assist_interrupt(processor, cia);
0.63,6.FRT,11./,16.FRB,21.15,31.Rc:X:f:fctiwz:Floating Convert To Integer Word with round towards Zero
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
convert_to_integer(processor, cia,
frT, *frB,
fpscr_rn_round_towards_zero, 32);
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
0.63,6.FRT,11./,16.FRB,21.846,31.Rc:X:64,f::Floating Convert from Integer Doubleword
int sign = EXTRACTED64(*frB, 0, 0);
int exp = 63;
uint64_t frac = *frB;
/***/
if (frac == 0) GOTO(Zero_Operand);
if (sign == 1) frac = ~frac + 1;
while (EXTRACTED64(frac, 0, 0) == 0) {
/*??? do the loop 0 times if (FRB) = max negative integer */
frac = INSERTED64(EXTRACTED64(frac, 1, 63), 0, 62);
exp = exp - 1;
}
Round_Float(processor, sign, &exp, &frac, FPSCR & fpscr_rn);
if (sign == 0) FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
if (sign == 1) FPSCR_SET_FPRF(fpscr_rf_pos_normal_number);
*frT = (INSERTED64(sign, 0, 0)
| INSERTED64(exp + 1023, 1, 11)
| INSERTED64(EXTRACTED64(frac, 1, 52), 12, 63));
GOTO(Done);
/**/
LABEL(Zero_Operand):
FPSCR_SET_FR(0);
FPSCR_SET_FI(0);
FPSCR_SET_FPRF(fpscr_rf_pos_zero);
*frT = 0;
GOTO(Done);
/**/
LABEL(Done):
PPC_INSN_FLOAT(FRT_BITMASK, FRB_BITMASK, Rc);
#
# I.4.6.7 Floating-Point Compare Instructions
#
0.63,6.BF,9./,11.FRA,16.FRB,21.0,31./:X:f:fcmpu:Floating Compare Unordered
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
unsigned c;
if (is_NaN(*frA, 0) || is_NaN(*frB, 0))
c = cr_i_summary_overflow; /* 0b0001 - (FRA) ? (FRB) */
else if (is_less_than(frA, frB))
c = cr_i_negative; /* 0b1000 - (FRA) < (FRB) */
else if (is_greater_than(frA, frB))
c = cr_i_positive; /* 0b0100 - (FRA) > (FRB) */
else
c = cr_i_zero; /* 0b0010 - (FRA) = (FRB) */
FPSCR_SET_FPCC(c);
CR_SET(BF, c); /* CR[4*BF..4*BF+3] = c */
if (is_SNaN(*frA, 0) || is_SNaN(*frB, 0))
FPSCR_OR_VX(fpscr_vxsnan);
FPSCR_END(0);
PPC_INSN_FLOAT_CR(0, FRA_BITMASK | FRB_BITMASK, BF_BITMASK);
0.63,6.BF,9./,11.FRA,16.FRB,21.32,31./:X:f:fcmpo:Floating Compare Ordered
*601: PPC_UNIT_FPU, PPC_UNIT_FPU, 4, 4, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
FPSCR_BEGIN;
unsigned c;
if (is_NaN(*frA, 0) || is_NaN(*frB, 0))
c = cr_i_summary_overflow; /* 0b0001 - (FRA) ? (FRB) */
else if (is_less_than(frA, frB))
c = cr_i_negative; /* 0b1000 - (FRA) < (FRB) */
else if (is_greater_than(frA, frB))
c = cr_i_positive; /* 0b0100 - (FRA) > (FRB) */
else
c = cr_i_zero; /* 0b0010 - (FRA) = (FRB) */
FPSCR_SET_FPCC(c);
CR_SET(BF, c); /* CR[4*BF..4*BF+3] = c */
if (is_SNaN(*frA, 0) || is_SNaN(*frB, 0)) {
FPSCR_OR_VX(fpscr_vxsnan);
if ((FPSCR & fpscr_ve) == 0)
FPSCR_OR_VX(fpscr_vxvc);
}
else if (is_QNaN(*frA, 0) || is_QNaN(*frB, 0)) {
FPSCR_OR_VX(fpscr_vxvc);
}
FPSCR_END(0);
PPC_INSN_FLOAT_CR(0, FRA_BITMASK | FRB_BITMASK, BF_BITMASK);
#
# I.4.6.8 Floating-Point Status and Control Register Instructions
#
0.63,6.FRT,11./,16./,21.583,31.Rc:X:f::Move From FPSCR
FPSCR_BEGIN;
*frT = FPSCR;
FPSCR_END(Rc);
0.63,6.BF,9./,11.BFA,14./,16./,21.64,31./:X:f::Move to Condition Register from FPSCR
FPSCR_BEGIN;
unsigned field = FPSCR_FIELD(BFA);
CR_SET(BF, field);
FPSCR_SET(BFA, 0); /* FPSCR_END fixes up FEX/VX */
FPSCR_END(0);
0.63,6.BF,9./,11./,16.U,20./,21.134,31.Rc:X:f::Move To FPSCR Field Immediate
FPSCR_BEGIN;
FPSCR_SET(BF, U);
FPSCR_END(Rc);
0.63,6./,7.FLM,15./,16.FRB,21.711,31.Rc:XFL:f::Move To FPSCR Fields
FPSCR_BEGIN;
int i;
for (i = 0; i < 8; i++) {
if ((FLM & BIT8(i))) {
FPSCR &= ~MASK32(i*4, i*4+3);
FPSCR |= MASKED32(*frB, i*4, i*4+3);
}
}
FPSCR_END(Rc);
0.63,6.BT,11./,16./,21.70,31.Rc:X:f::Move To FPSCR Bit 0
FPSCR_BEGIN;
uint32_t bit = BIT32(BT);
FPSCR &= ~bit;
FPSCR_END(Rc);
0.63,6.BT,11./,16./,21.38,31.Rc:X:f::Move To FPSCR Bit 1
FPSCR_BEGIN;
uint32_t bit = BIT32(BT);
if (bit & fpscr_fi)
bit |= fpscr_xx;
if ((bit & fpscr_vx_bits))
bit |= fpscr_fx;
/* note - omit vx bit */
if ((bit & (fpscr_ox | fpscr_ux | fpscr_zx | fpscr_xx)))
bit |= fpscr_fx;
FPSCR |= bit;
FPSCR_END(Rc);
#
# I.A.1.2 Floating-Point Arithmetic Instructions
#
0.63,6.FRT,11./,16.FRB,21./,26.22,31.Rc:A:f,o::Floating Square Root
program_interrupt(processor, cia, optional_instruction_program_interrupt);
0.59,6.FRT,11./,16.FRB,21./,26.22,31.Rc:A:f,o::Floating Square Root Single
program_interrupt(processor, cia, optional_instruction_program_interrupt);
0.59,6.FRT,11./,16.FRB,21./,26.24,31.Rc:A:f,o::Floating Reciprocal Estimate Single
program_interrupt(processor, cia, optional_instruction_program_interrupt);
0.63,6.FRT,11./,16.FRB,21./,26.26,31.Rc:A:f,o::Floating Reciprocal Square Root Estimate
program_interrupt(processor, cia, optional_instruction_program_interrupt);
#
# I.A.1.3 Floating-Point Select Instruction
#
0.63,6.FRT,11.FRA,16.FRB,21.FRC,26.23,31.Rc:A:f,o::Floating Select
*601: PPC_UNIT_BAD, PPC_UNIT_BAD, 0, 0, 0
*603: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*603e:PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
*604: PPC_UNIT_FPU, PPC_UNIT_FPU, 1, 3, 0
if (CURRENT_MODEL == MODEL_ppc601) {
program_interrupt(processor, cia, optional_instruction_program_interrupt);
} else {
uint64_t zero = 0;
FPSCR_BEGIN;
if (is_NaN(*frA, 0) || is_less_than (frA, &zero)) *frT = *frB;
else *frT = *frC;
FPSCR_END(Rc);
PPC_INSN_FLOAT(FRT_BITMASK, FRA_BITMASK | FRB_BITMASK | FRC_BITMASK, Rc);
}
#
# II.3.2 Cache Management Instructions
#
0.31,6./,11.RA,16.RB,21.982,31./:X::icbi:Instruction Cache Block Invalidate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 1, 0
/* blindly flush all instruction cache entries */
#if WITH_IDECODE_CACHE_SIZE
cpu_flush_icache(processor);
#endif
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK, 0);
0.19,6./,11./,16./,21.150,31./:XL::isync:Instruction Synchronize
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 1, 0
cpu_synchronize_context(processor, cia);
PPC_INSN_INT(0, 0, 0);
#
# II.3.2.2 Data Cache Instructions
#
0.31,6./,11.RA,16.RB,21.278,31./:X:::Data Cache Block Touch
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 2, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 2, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 1, 0
TRACE(trace_tbd,("Data Cache Block Touch\n"));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK, 0/*Rc*/);
0.31,6./,11.RA,16.RB,21.246,31./:X:::Data Cache Block Touch for Store
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 2, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 2, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
TRACE(trace_tbd,("Data Cache Block Touch for Store\n"));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK, 0/*Rc*/);
0.31,6./,11.RA,16.RB,21.1014,31./:X:::Data Cache Block set to Zero
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 10, 10, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 10, 10, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
TRACE(trace_tbd,("Data Cache Block set to Zero\n"));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK, 0/*Rc*/);
0.31,6./,11.RA,16.RB,21.54,31./:X:::Data Cache Block Store
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 5, 5, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 5, 5, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 1, 0
TRACE(trace_tbd,("Data Cache Block Store\n"));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK, 0/*Rc*/);
0.31,6./,11.RA,16.RB,21.86,31./:X:::Data Cache Block Flush
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 5, 5, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 5, 5, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 1, 0
TRACE(trace_tbd,("Data Cache Block Flush\n"));
PPC_INSN_INT(0, (RA_BITMASK & ~1) | RB_BITMASK, 0/*Rc*/);
#
# II.3.3 Enforce In-order Execution of I/O Instruction
#
0.31,6./,11./,16./,21.854,31./:X::eieio:Enforce In-order Execution of I/O
/* Since this model has no instruction overlap
this instruction need do nothing */
#
# II.4.1 Time Base Instructions
#
0.31,6.RT,11.tbr,21.371,31./:XFX::mftb:Move From Time Base
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 3, 3, 0
int n = (tbr{5:9} << 5) | tbr{0:4};
if (n == 268) {
if (is_64bit_implementation) *rT = TB;
else *rT = EXTRACTED64(TB, 32, 63);
}
else if (n == 269) {
if (is_64bit_implementation) *rT = EXTRACTED64(TB, 0, 31);
else *rT = EXTRACTED64(TB, 0, 31);
}
else
program_interrupt(processor, cia,
illegal_instruction_program_interrupt);
#
# III.2.3.1 System Linkage Instructions
#
0.19,6./,11./,16./,21.50,31./:XL::rfi:Return From Interrupt
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 3, 3, 0
if (IS_PROBLEM_STATE(processor)) {
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
}
else {
MSR = (MASKED(SRR1, 0, 32)
| MASKED(SRR1, 37, 41)
| MASKED(SRR1, 48, 63));
NIA = MASKED(SRR0, 0, 61);
cpu_synchronize_context(processor, cia);
check_masked_interrupts(processor);
}
#
# III.3.4.1 Move to/from System Register Instructions
#
#0.31,6.RS,11.SPR,21.467,31./:XFX:::Move To Special Purpose Register
#0.31,6.RT,11.SPR,21.339,31./:XFX:::Move From Special Purpose Register
0.31,6.RS,11./,16./,21.146,31./:X:::Move To Machine State Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else {
MSR = *rS;
check_masked_interrupts(processor);
}
0.31,6.RT,11./,16./,21.83,31./:X:::Move From Machine State Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 1, 1, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 3, 3, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else {
*rT = MSR;
check_masked_interrupts(processor);
}
#
# III.4.11.1 Cache Management Instructions
#
0.31,6./,11.RA,16.RB,21.470,31./:X::dcbi:Data Cache Block Invalidate
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_LSU, PPC_UNIT_LSU, 2, 2, 0
*603e:PPC_UNIT_LSU, PPC_UNIT_LSU, 2, 2, 0
*604: PPC_UNIT_LSU, PPC_UNIT_LSU, 1, 3, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else
TRACE(trace_tbd,("Data Cache Block Invalidate\n"));
#
# III.4.11.2 Segment Register Manipulation Instructions
#
0.31,6.RS,11./,12.SR,16./,21.210,31./:X:32:mtsr %SR,%RS:Move To Segment Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else
SEGREG(SR) = *rS;
0.31,6.RS,11./,16.RB,21.242,31./:X:32:mtsrin %RS,%RB:Move To Segment Register Indirect
*601: PPC_UNIT_IU, PPC_UNIT_IU, 1, 1, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 2, 2, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else
SEGREG(EXTRACTED32(*rB, 0, 3)) = *rS;
0.31,6.RT,11./,12.SR,16./,21.595,31./:X:32:mfsr %RT,%RS:Move From Segment Register
*601: PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else
*rT = SEGREG(SR);
0.31,6.RT,11./,16.RB,21.659,31./:X:32:mfsrin %RT,%RB:Move From Segment Register Indirect
*601: PPC_UNIT_IU, PPC_UNIT_IU, 2, 2, 0
*603: PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*603e:PPC_UNIT_SRU, PPC_UNIT_SRU, 3, 3, 0
*604: PPC_UNIT_MCIU, PPC_UNIT_MCIU, 1, 1, 0
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else
*rT = SEGREG(EXTRACTED32(*rB, 0, 3));
#
# III.4.11.3 Lookaside Buffer Management Instructions (Optional)
#
0.31,6./,11./,16.RB,21.434,31./:X:64::SLB Invalidate Entry
0.31,6./,11./,16./,21.498,31./:X:64::SLB Invalidate All
0.31,6./,11./,16.RB,21.306,31./:X:::TLB Invalidate Entry
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else {
int nr = 0;
cpu *proc;
while (1) {
proc = psim_cpu(cpu_system(processor), nr);
if (proc == NULL) break;
cpu_page_tlb_invalidate_entry(proc, *rB);
nr++;
}
}
0.31,6./,11./,16./,21.370,31./:X:::TLB Invalidate All
if (IS_PROBLEM_STATE(processor))
program_interrupt(processor, cia,
privileged_instruction_program_interrupt);
else {
int nr = 0;
cpu *proc;
while (1) {
proc = psim_cpu(cpu_system(processor), nr);
if (proc == NULL) break;
cpu_page_tlb_invalidate_all(proc);
nr++;
}
}
0.31,6./,11./,16./,21.566,31./:X:::TLB Synchronize
/* nothing happens here - always in sync */
#
# III.A.1.2 External Access Instructions
#
0.31,6.RT,11.RA,16.RB,21.310,31./:X:earwax::External Control In Word Indexed
0.31,6.RS,11.RA,16.RB,21.438,31./:X:earwax::External Control Out Word Indexed
:include:::altivec.igen
:include:::e500.igen