qemu-e2k/target/hexagon/decode.c
Matheus Tavares Bernardino 14edcf11e2 Hexagon (decode): look for pkts with multiple insns at the same slot
Each slot in a packet can be assigned to at most one instruction.
Although the assembler generally ought to enforce this rule, we better
be safe than sorry and also do some check to properly throw an "invalid
packet" exception on wrong slot assignments.

This should also make it easier to debug possible future errors caused
by missing updates to `find_iclass_slots()` rules in
target/hexagon/iclass.c.

Co-authored-by: Taylor Simpson <tsimpson@quicinc.com>
Signed-off-by: Taylor Simpson <tsimpson@quicinc.com>
Signed-off-by: Matheus Tavares Bernardino <quic_mathbern@quicinc.com>
Reviewed-by: Taylor Simpson <tsimpson@quicinc.com>
Tested-by: Taylor Simpson <tsimpson@quicinc.com>
Message-Id: <f8b829443523568823d062adf8bf6659bc6d4a3f.1683552984.git.quic_mathbern@quicinc.com>
2023-05-18 12:40:52 -07:00

1019 lines
31 KiB
C

/*
* Copyright(c) 2019-2023 Qualcomm Innovation Center, Inc. All Rights Reserved.
*
* 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 2 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/>.
*/
#include "qemu/osdep.h"
#include "iclass.h"
#include "attribs.h"
#include "genptr.h"
#include "decode.h"
#include "insn.h"
#include "printinsn.h"
#include "mmvec/decode_ext_mmvec.h"
#define fZXTN(N, M, VAL) ((VAL) & ((1LL << (N)) - 1))
enum {
EXT_IDX_noext = 0,
EXT_IDX_noext_AFTER = 4,
EXT_IDX_mmvec = 4,
EXT_IDX_mmvec_AFTER = 8,
XX_LAST_EXT_IDX
};
/*
* Certain operand types represent a non-contiguous set of values.
* For example, the compound compare-and-jump instruction can only access
* registers R0-R7 and R16-23.
* This table represents the mapping from the encoding to the actual values.
*/
#define DEF_REGMAP(NAME, ELEMENTS, ...) \
static const unsigned int DECODE_REGISTER_##NAME[ELEMENTS] = \
{ __VA_ARGS__ };
/* Name Num Table */
DEF_REGMAP(R_16, 16, 0, 1, 2, 3, 4, 5, 6, 7, 16, 17, 18, 19, 20, 21, 22, 23)
DEF_REGMAP(R__8, 8, 0, 2, 4, 6, 16, 18, 20, 22)
DEF_REGMAP(R_8, 8, 0, 1, 2, 3, 4, 5, 6, 7)
#define DECODE_MAPPED_REG(OPNUM, NAME) \
insn->regno[OPNUM] = DECODE_REGISTER_##NAME[insn->regno[OPNUM]];
typedef struct {
const struct DectreeTable *table_link;
const struct DectreeTable *table_link_b;
Opcode opcode;
enum {
DECTREE_ENTRY_INVALID,
DECTREE_TABLE_LINK,
DECTREE_SUBINSNS,
DECTREE_EXTSPACE,
DECTREE_TERMINAL
} type;
} DectreeEntry;
typedef struct DectreeTable {
unsigned int (*lookup_function)(int startbit, int width, uint32_t opcode);
unsigned int size;
unsigned int startbit;
unsigned int width;
const DectreeEntry table[];
} DectreeTable;
#define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) \
static const DectreeTable dectree_table_##TAG;
#define TABLE_LINK(TABLE) /* NOTHING */
#define TERMINAL(TAG, ENC) /* NOTHING */
#define SUBINSNS(TAG, CLASSA, CLASSB, ENC) /* NOTHING */
#define EXTSPACE(TAG, ENC) /* NOTHING */
#define INVALID() /* NOTHING */
#define DECODE_END_TABLE(...) /* NOTHING */
#define DECODE_MATCH_INFO(...) /* NOTHING */
#define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */
#define DECODE_OPINFO(...) /* NOTHING */
#include "dectree_generated.h.inc"
#undef DECODE_OPINFO
#undef DECODE_MATCH_INFO
#undef DECODE_LEGACY_MATCH_INFO
#undef DECODE_END_TABLE
#undef INVALID
#undef TERMINAL
#undef SUBINSNS
#undef EXTSPACE
#undef TABLE_LINK
#undef DECODE_NEW_TABLE
#undef DECODE_SEPARATOR_BITS
#define DECODE_SEPARATOR_BITS(START, WIDTH) NULL, START, WIDTH
#define DECODE_NEW_TABLE_HELPER(TAG, SIZE, FN, START, WIDTH) \
static const DectreeTable dectree_table_##TAG = { \
.size = SIZE, \
.lookup_function = FN, \
.startbit = START, \
.width = WIDTH, \
.table = {
#define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) \
DECODE_NEW_TABLE_HELPER(TAG, SIZE, WHATNOT)
#define TABLE_LINK(TABLE) \
{ .type = DECTREE_TABLE_LINK, .table_link = &dectree_table_##TABLE },
#define TERMINAL(TAG, ENC) \
{ .type = DECTREE_TERMINAL, .opcode = TAG },
#define SUBINSNS(TAG, CLASSA, CLASSB, ENC) \
{ \
.type = DECTREE_SUBINSNS, \
.table_link = &dectree_table_DECODE_SUBINSN_##CLASSA, \
.table_link_b = &dectree_table_DECODE_SUBINSN_##CLASSB \
},
#define EXTSPACE(TAG, ENC) { .type = DECTREE_EXTSPACE },
#define INVALID() { .type = DECTREE_ENTRY_INVALID, .opcode = XX_LAST_OPCODE },
#define DECODE_END_TABLE(...) } };
#define DECODE_MATCH_INFO(...) /* NOTHING */
#define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */
#define DECODE_OPINFO(...) /* NOTHING */
#include "dectree_generated.h.inc"
#undef DECODE_OPINFO
#undef DECODE_MATCH_INFO
#undef DECODE_LEGACY_MATCH_INFO
#undef DECODE_END_TABLE
#undef INVALID
#undef TERMINAL
#undef SUBINSNS
#undef EXTSPACE
#undef TABLE_LINK
#undef DECODE_NEW_TABLE
#undef DECODE_NEW_TABLE_HELPER
#undef DECODE_SEPARATOR_BITS
static const DectreeTable dectree_table_DECODE_EXT_EXT_noext = {
.size = 1, .lookup_function = NULL, .startbit = 0, .width = 0,
.table = {
{ .type = DECTREE_ENTRY_INVALID, .opcode = XX_LAST_OPCODE },
}
};
static const DectreeTable *ext_trees[XX_LAST_EXT_IDX];
static void decode_ext_init(void)
{
int i;
for (i = EXT_IDX_noext; i < EXT_IDX_noext_AFTER; i++) {
ext_trees[i] = &dectree_table_DECODE_EXT_EXT_noext;
}
for (i = EXT_IDX_mmvec; i < EXT_IDX_mmvec_AFTER; i++) {
ext_trees[i] = &dectree_table_DECODE_EXT_EXT_mmvec;
}
}
typedef struct {
uint32_t mask;
uint32_t match;
} DecodeITableEntry;
#define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) /* NOTHING */
#define TABLE_LINK(TABLE) /* NOTHING */
#define TERMINAL(TAG, ENC) /* NOTHING */
#define SUBINSNS(TAG, CLASSA, CLASSB, ENC) /* NOTHING */
#define EXTSPACE(TAG, ENC) /* NOTHING */
#define INVALID() /* NOTHING */
#define DECODE_END_TABLE(...) /* NOTHING */
#define DECODE_OPINFO(...) /* NOTHING */
#define DECODE_MATCH_INFO_NORMAL(TAG, MASK, MATCH) \
[TAG] = { \
.mask = MASK, \
.match = MATCH, \
},
#define DECODE_MATCH_INFO_NULL(TAG, MASK, MATCH) \
[TAG] = { .match = ~0 },
#define DECODE_MATCH_INFO(...) DECODE_MATCH_INFO_NORMAL(__VA_ARGS__)
#define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */
static const DecodeITableEntry decode_itable[XX_LAST_OPCODE] = {
#include "dectree_generated.h.inc"
};
#undef DECODE_MATCH_INFO
#define DECODE_MATCH_INFO(...) DECODE_MATCH_INFO_NULL(__VA_ARGS__)
#undef DECODE_LEGACY_MATCH_INFO
#define DECODE_LEGACY_MATCH_INFO(...) DECODE_MATCH_INFO_NORMAL(__VA_ARGS__)
static const DecodeITableEntry decode_legacy_itable[XX_LAST_OPCODE] = {
#include "dectree_generated.h.inc"
};
#undef DECODE_OPINFO
#undef DECODE_MATCH_INFO
#undef DECODE_LEGACY_MATCH_INFO
#undef DECODE_END_TABLE
#undef INVALID
#undef TERMINAL
#undef SUBINSNS
#undef EXTSPACE
#undef TABLE_LINK
#undef DECODE_NEW_TABLE
#undef DECODE_SEPARATOR_BITS
void decode_init(void)
{
decode_ext_init();
}
void decode_send_insn_to(Packet *packet, int start, int newloc)
{
Insn tmpinsn;
int direction;
int i;
if (start == newloc) {
return;
}
if (start < newloc) {
/* Move towards end */
direction = 1;
} else {
/* move towards beginning */
direction = -1;
}
for (i = start; i != newloc; i += direction) {
tmpinsn = packet->insn[i];
packet->insn[i] = packet->insn[i + direction];
packet->insn[i + direction] = tmpinsn;
}
}
/* Fill newvalue registers with the correct regno */
static void
decode_fill_newvalue_regno(Packet *packet)
{
int i, use_regidx, offset, def_idx, dst_idx;
uint16_t def_opcode, use_opcode;
char *dststr;
for (i = 1; i < packet->num_insns; i++) {
if (GET_ATTRIB(packet->insn[i].opcode, A_DOTNEWVALUE) &&
!GET_ATTRIB(packet->insn[i].opcode, A_EXTENSION)) {
use_opcode = packet->insn[i].opcode;
/* It's a store, so we're adjusting the Nt field */
if (GET_ATTRIB(use_opcode, A_STORE)) {
use_regidx = strchr(opcode_reginfo[use_opcode], 't') -
opcode_reginfo[use_opcode];
} else { /* It's a Jump, so we're adjusting the Ns field */
use_regidx = strchr(opcode_reginfo[use_opcode], 's') -
opcode_reginfo[use_opcode];
}
/*
* What's encoded at the N-field is the offset to who's producing
* the value. Shift off the LSB which indicates odd/even register,
* then walk backwards and skip over the constant extenders.
*/
offset = packet->insn[i].regno[use_regidx] >> 1;
def_idx = i - offset;
for (int j = 0; j < offset; j++) {
if (GET_ATTRIB(packet->insn[i - j - 1].opcode, A_IT_EXTENDER)) {
def_idx--;
}
}
/*
* Check for a badly encoded N-field which points to an instruction
* out-of-range
*/
g_assert(!((def_idx < 0) || (def_idx > (packet->num_insns - 1))));
/*
* packet->insn[def_idx] is the producer
* Figure out which type of destination it produces
* and the corresponding index in the reginfo
*/
def_opcode = packet->insn[def_idx].opcode;
dststr = strstr(opcode_wregs[def_opcode], "Rd");
if (dststr) {
dststr = strchr(opcode_reginfo[def_opcode], 'd');
} else {
dststr = strstr(opcode_wregs[def_opcode], "Rx");
if (dststr) {
dststr = strchr(opcode_reginfo[def_opcode], 'x');
} else {
dststr = strstr(opcode_wregs[def_opcode], "Re");
if (dststr) {
dststr = strchr(opcode_reginfo[def_opcode], 'e');
} else {
dststr = strstr(opcode_wregs[def_opcode], "Ry");
if (dststr) {
dststr = strchr(opcode_reginfo[def_opcode], 'y');
} else {
g_assert_not_reached();
}
}
}
}
g_assert(dststr != NULL);
/* Now patch up the consumer with the register number */
dst_idx = dststr - opcode_reginfo[def_opcode];
packet->insn[i].regno[use_regidx] =
packet->insn[def_idx].regno[dst_idx];
/*
* We need to remember who produces this value to later
* check if it was dynamically cancelled
*/
packet->insn[i].new_value_producer_slot =
packet->insn[def_idx].slot;
}
}
}
/* Split CJ into a compare and a jump */
static void decode_split_cmpjump(Packet *pkt)
{
int last, i;
int numinsns = pkt->num_insns;
/*
* First, split all compare-jumps.
* The compare is sent to the end as a new instruction.
* Do it this way so we don't reorder dual jumps. Those need to stay in
* original order.
*/
for (i = 0; i < numinsns; i++) {
/* It's a cmp-jump */
if (GET_ATTRIB(pkt->insn[i].opcode, A_NEWCMPJUMP)) {
last = pkt->num_insns;
pkt->insn[last] = pkt->insn[i]; /* copy the instruction */
pkt->insn[last].part1 = true; /* last insn does the CMP */
pkt->insn[i].part1 = false; /* existing insn does the JUMP */
pkt->num_insns++;
}
}
/* Now re-shuffle all the compares back to the beginning */
for (i = 0; i < pkt->num_insns; i++) {
if (pkt->insn[i].part1) {
decode_send_insn_to(pkt, i, 0);
}
}
}
static bool decode_opcode_can_jump(int opcode)
{
if ((GET_ATTRIB(opcode, A_JUMP)) ||
(GET_ATTRIB(opcode, A_CALL)) ||
(opcode == J2_trap0) ||
(opcode == J2_pause)) {
/* Exception to A_JUMP attribute */
if (opcode == J4_hintjumpr) {
return false;
}
return true;
}
return false;
}
static bool decode_opcode_ends_loop(int opcode)
{
return GET_ATTRIB(opcode, A_HWLOOP0_END) ||
GET_ATTRIB(opcode, A_HWLOOP1_END);
}
/* Set the is_* fields in each instruction */
static void decode_set_insn_attr_fields(Packet *pkt)
{
int i;
int numinsns = pkt->num_insns;
uint16_t opcode;
pkt->pkt_has_cof = false;
pkt->pkt_has_multi_cof = false;
pkt->pkt_has_endloop = false;
pkt->pkt_has_dczeroa = false;
for (i = 0; i < numinsns; i++) {
opcode = pkt->insn[i].opcode;
if (pkt->insn[i].part1) {
continue; /* Skip compare of cmp-jumps */
}
if (GET_ATTRIB(opcode, A_DCZEROA)) {
pkt->pkt_has_dczeroa = true;
}
if (GET_ATTRIB(opcode, A_STORE)) {
if (GET_ATTRIB(opcode, A_SCALAR_STORE) &&
!GET_ATTRIB(opcode, A_MEMSIZE_0B)) {
if (pkt->insn[i].slot == 0) {
pkt->pkt_has_store_s0 = true;
} else {
pkt->pkt_has_store_s1 = true;
}
}
}
if (decode_opcode_can_jump(opcode)) {
if (pkt->pkt_has_cof) {
pkt->pkt_has_multi_cof = true;
}
pkt->pkt_has_cof = true;
}
pkt->insn[i].is_endloop = decode_opcode_ends_loop(opcode);
pkt->pkt_has_endloop |= pkt->insn[i].is_endloop;
if (pkt->pkt_has_endloop) {
if (pkt->pkt_has_cof) {
pkt->pkt_has_multi_cof = true;
}
pkt->pkt_has_cof = true;
}
}
}
/*
* Shuffle for execution
* Move stores to end (in same order as encoding)
* Move compares to beginning (for use by .new insns)
*/
static void decode_shuffle_for_execution(Packet *packet)
{
bool changed = false;
int i;
bool flag; /* flag means we've seen a non-memory instruction */
int n_mems;
int last_insn = packet->num_insns - 1;
/*
* Skip end loops, somehow an end loop is getting in and messing
* up the order
*/
if (decode_opcode_ends_loop(packet->insn[last_insn].opcode)) {
last_insn--;
}
do {
changed = false;
/*
* Stores go last, must not reorder.
* Cannot shuffle stores past loads, either.
* Iterate backwards. If we see a non-memory instruction,
* then a store, shuffle the store to the front. Don't shuffle
* stores wrt each other or a load.
*/
for (flag = false, n_mems = 0, i = last_insn; i >= 0; i--) {
int opcode = packet->insn[i].opcode;
if (flag && GET_ATTRIB(opcode, A_STORE)) {
decode_send_insn_to(packet, i, last_insn - n_mems);
n_mems++;
changed = true;
} else if (GET_ATTRIB(opcode, A_STORE)) {
n_mems++;
} else if (GET_ATTRIB(opcode, A_LOAD)) {
/*
* Don't set flag, since we don't want to shuffle a
* store past a load
*/
n_mems++;
} else if (GET_ATTRIB(opcode, A_DOTNEWVALUE)) {
/*
* Don't set flag, since we don't want to shuffle past
* a .new value
*/
} else {
flag = true;
}
}
if (changed) {
continue;
}
/* Compares go first, may be reordered wrt each other */
for (flag = false, i = 0; i < last_insn + 1; i++) {
int opcode = packet->insn[i].opcode;
if ((strstr(opcode_wregs[opcode], "Pd4") ||
strstr(opcode_wregs[opcode], "Pe4")) &&
GET_ATTRIB(opcode, A_STORE) == 0) {
/* This should be a compare (not a store conditional) */
if (flag) {
decode_send_insn_to(packet, i, 0);
changed = true;
continue;
}
} else if (GET_ATTRIB(opcode, A_IMPLICIT_WRITES_P3) &&
!decode_opcode_ends_loop(packet->insn[i].opcode)) {
/*
* spNloop instruction
* Don't reorder endloops; they are not valid for .new uses,
* and we want to match HW
*/
if (flag) {
decode_send_insn_to(packet, i, 0);
changed = true;
continue;
}
} else if (GET_ATTRIB(opcode, A_IMPLICIT_WRITES_P0) &&
!GET_ATTRIB(opcode, A_NEWCMPJUMP)) {
if (flag) {
decode_send_insn_to(packet, i, 0);
changed = true;
continue;
}
} else {
flag = true;
}
}
if (changed) {
continue;
}
} while (changed);
/*
* If we have a .new register compare/branch, move that to the very
* very end, past stores
*/
for (i = 0; i < last_insn; i++) {
if (GET_ATTRIB(packet->insn[i].opcode, A_DOTNEWVALUE)) {
decode_send_insn_to(packet, i, last_insn);
break;
}
}
}
static void
apply_extender(Packet *pkt, int i, uint32_t extender)
{
int immed_num;
uint32_t base_immed;
immed_num = opcode_which_immediate_is_extended(pkt->insn[i].opcode);
base_immed = pkt->insn[i].immed[immed_num];
pkt->insn[i].immed[immed_num] = extender | fZXTN(6, 32, base_immed);
}
static void decode_apply_extenders(Packet *packet)
{
int i;
for (i = 0; i < packet->num_insns; i++) {
if (GET_ATTRIB(packet->insn[i].opcode, A_IT_EXTENDER)) {
packet->insn[i + 1].extension_valid = true;
apply_extender(packet, i + 1, packet->insn[i].immed[0]);
}
}
}
static void decode_remove_extenders(Packet *packet)
{
int i, j;
for (i = 0; i < packet->num_insns; i++) {
if (GET_ATTRIB(packet->insn[i].opcode, A_IT_EXTENDER)) {
/* Remove this one by moving the remaining instructions down */
for (j = i;
(j < packet->num_insns - 1) && (j < INSTRUCTIONS_MAX - 1);
j++) {
packet->insn[j] = packet->insn[j + 1];
}
packet->num_insns--;
}
}
}
static SlotMask get_valid_slots(const Packet *pkt, unsigned int slot)
{
if (GET_ATTRIB(pkt->insn[slot].opcode, A_EXTENSION)) {
return mmvec_ext_decode_find_iclass_slots(pkt->insn[slot].opcode);
} else {
return find_iclass_slots(pkt->insn[slot].opcode,
pkt->insn[slot].iclass);
}
}
#define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) /* NOTHING */
#define TABLE_LINK(TABLE) /* NOTHING */
#define TERMINAL(TAG, ENC) /* NOTHING */
#define SUBINSNS(TAG, CLASSA, CLASSB, ENC) /* NOTHING */
#define EXTSPACE(TAG, ENC) /* NOTHING */
#define INVALID() /* NOTHING */
#define DECODE_END_TABLE(...) /* NOTHING */
#define DECODE_MATCH_INFO(...) /* NOTHING */
#define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */
#define DECODE_REG(REGNO, WIDTH, STARTBIT) \
insn->regno[REGNO] = ((encoding >> STARTBIT) & ((1 << WIDTH) - 1));
#define DECODE_IMPL_REG(REGNO, VAL) \
insn->regno[REGNO] = VAL;
#define DECODE_IMM(IMMNO, WIDTH, STARTBIT, VALSTART) \
insn->immed[IMMNO] |= (((encoding >> STARTBIT) & ((1 << WIDTH) - 1))) << \
(VALSTART);
#define DECODE_IMM_SXT(IMMNO, WIDTH) \
insn->immed[IMMNO] = ((((int32_t)insn->immed[IMMNO]) << (32 - WIDTH)) >> \
(32 - WIDTH));
#define DECODE_IMM_NEG(IMMNO, WIDTH) \
insn->immed[IMMNO] = -insn->immed[IMMNO];
#define DECODE_IMM_SHIFT(IMMNO, SHAMT) \
if ((!insn->extension_valid) || \
(insn->which_extended != IMMNO)) { \
insn->immed[IMMNO] <<= SHAMT; \
}
#define DECODE_OPINFO(TAG, BEH) \
case TAG: \
{ BEH } \
break; \
/*
* Fill in the operands of the instruction
* dectree_generated.h.inc has a DECODE_OPINFO entry for each opcode
* For example,
* DECODE_OPINFO(A2_addi,
* DECODE_REG(0,5,0)
* DECODE_REG(1,5,16)
* DECODE_IMM(0,7,21,9)
* DECODE_IMM(0,9,5,0)
* DECODE_IMM_SXT(0,16)
* with the macros defined above, we'll fill in a switch statement
* where each case is an opcode tag.
*/
static void
decode_op(Insn *insn, Opcode tag, uint32_t encoding)
{
insn->immed[0] = 0;
insn->immed[1] = 0;
insn->opcode = tag;
if (insn->extension_valid) {
insn->which_extended = opcode_which_immediate_is_extended(tag);
}
switch (tag) {
#include "dectree_generated.h.inc"
default:
break;
}
insn->generate = opcode_genptr[tag];
insn->iclass = iclass_bits(encoding);
}
#undef DECODE_REG
#undef DECODE_IMPL_REG
#undef DECODE_IMM
#undef DECODE_IMM_SHIFT
#undef DECODE_OPINFO
#undef DECODE_MATCH_INFO
#undef DECODE_LEGACY_MATCH_INFO
#undef DECODE_END_TABLE
#undef INVALID
#undef TERMINAL
#undef SUBINSNS
#undef EXTSPACE
#undef TABLE_LINK
#undef DECODE_NEW_TABLE
#undef DECODE_SEPARATOR_BITS
static unsigned int
decode_subinsn_tablewalk(Insn *insn, const DectreeTable *table,
uint32_t encoding)
{
unsigned int i;
Opcode opc;
if (table->lookup_function) {
i = table->lookup_function(table->startbit, table->width, encoding);
} else {
i = extract32(encoding, table->startbit, table->width);
}
if (table->table[i].type == DECTREE_TABLE_LINK) {
return decode_subinsn_tablewalk(insn, table->table[i].table_link,
encoding);
} else if (table->table[i].type == DECTREE_TERMINAL) {
opc = table->table[i].opcode;
if ((encoding & decode_itable[opc].mask) != decode_itable[opc].match) {
return 0;
}
decode_op(insn, opc, encoding);
return 1;
} else {
return 0;
}
}
static unsigned int get_insn_a(uint32_t encoding)
{
return extract32(encoding, 0, 13);
}
static unsigned int get_insn_b(uint32_t encoding)
{
return extract32(encoding, 16, 13);
}
static unsigned int
decode_insns_tablewalk(Insn *insn, const DectreeTable *table,
uint32_t encoding)
{
unsigned int i;
unsigned int a, b;
Opcode opc;
if (table->lookup_function) {
i = table->lookup_function(table->startbit, table->width, encoding);
} else {
i = extract32(encoding, table->startbit, table->width);
}
if (table->table[i].type == DECTREE_TABLE_LINK) {
return decode_insns_tablewalk(insn, table->table[i].table_link,
encoding);
} else if (table->table[i].type == DECTREE_SUBINSNS) {
a = get_insn_a(encoding);
b = get_insn_b(encoding);
b = decode_subinsn_tablewalk(insn, table->table[i].table_link_b, b);
a = decode_subinsn_tablewalk(insn + 1, table->table[i].table_link, a);
if ((a == 0) || (b == 0)) {
return 0;
}
return 2;
} else if (table->table[i].type == DECTREE_TERMINAL) {
opc = table->table[i].opcode;
if ((encoding & decode_itable[opc].mask) != decode_itable[opc].match) {
if ((encoding & decode_legacy_itable[opc].mask) !=
decode_legacy_itable[opc].match) {
return 0;
}
}
decode_op(insn, opc, encoding);
return 1;
} else if (table->table[i].type == DECTREE_EXTSPACE) {
/*
* For now, HVX will be the only coproc
*/
return decode_insns_tablewalk(insn, ext_trees[EXT_IDX_mmvec], encoding);
} else {
return 0;
}
}
static unsigned int
decode_insns(Insn *insn, uint32_t encoding)
{
const DectreeTable *table;
if (parse_bits(encoding) != 0) {
/* Start with PP table - 32 bit instructions */
table = &dectree_table_DECODE_ROOT_32;
} else {
/* start with EE table - duplex instructions */
table = &dectree_table_DECODE_ROOT_EE;
}
return decode_insns_tablewalk(insn, table, encoding);
}
static void decode_add_endloop_insn(Insn *insn, int loopnum)
{
if (loopnum == 10) {
insn->opcode = J2_endloop01;
insn->generate = opcode_genptr[J2_endloop01];
} else if (loopnum == 1) {
insn->opcode = J2_endloop1;
insn->generate = opcode_genptr[J2_endloop1];
} else if (loopnum == 0) {
insn->opcode = J2_endloop0;
insn->generate = opcode_genptr[J2_endloop0];
} else {
g_assert_not_reached();
}
}
static bool decode_parsebits_is_loopend(uint32_t encoding32)
{
uint32_t bits = parse_bits(encoding32);
return bits == 0x2;
}
static bool has_valid_slot_assignment(Packet *pkt)
{
int used_slots = 0;
for (int i = 0; i < pkt->num_insns; i++) {
int slot_mask;
Insn *insn = &pkt->insn[i];
if (decode_opcode_ends_loop(insn->opcode)) {
/* We overload slot 0 for endloop. */
continue;
}
slot_mask = 1 << insn->slot;
if (used_slots & slot_mask) {
return false;
}
used_slots |= slot_mask;
}
return true;
}
static bool
decode_set_slot_number(Packet *pkt)
{
int slot;
int i;
bool hit_mem_insn = false;
bool hit_duplex = false;
bool slot0_found = false;
bool slot1_found = false;
int slot1_iidx = 0;
/*
* The slots are encoded in reverse order
* For each instruction, count down until you find a suitable slot
*/
for (i = 0, slot = 3; i < pkt->num_insns; i++) {
SlotMask valid_slots = get_valid_slots(pkt, i);
while (!(valid_slots & (1 << slot))) {
slot--;
}
pkt->insn[i].slot = slot;
if (slot) {
/* I've assigned the slot, now decrement it for the next insn */
slot--;
}
}
/* Fix the exceptions - mem insns to slot 0,1 */
for (i = pkt->num_insns - 1; i >= 0; i--) {
/* First memory instruction always goes to slot 0 */
if ((GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE) ||
GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE_PACKET_RULES)) &&
!hit_mem_insn) {
hit_mem_insn = true;
pkt->insn[i].slot = 0;
continue;
}
/* Next memory instruction always goes to slot 1 */
if ((GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE) ||
GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE_PACKET_RULES)) &&
hit_mem_insn) {
pkt->insn[i].slot = 1;
}
}
/* Fix the exceptions - duplex always slot 0,1 */
for (i = pkt->num_insns - 1; i >= 0; i--) {
/* First subinsn always goes to slot 0 */
if (GET_ATTRIB(pkt->insn[i].opcode, A_SUBINSN) && !hit_duplex) {
hit_duplex = true;
pkt->insn[i].slot = 0;
continue;
}
/* Next subinsn always goes to slot 1 */
if (GET_ATTRIB(pkt->insn[i].opcode, A_SUBINSN) && hit_duplex) {
pkt->insn[i].slot = 1;
}
}
/* Fix the exceptions - slot 1 is never empty, always aligns to slot 0 */
for (i = pkt->num_insns - 1; i >= 0; i--) {
/* Is slot0 used? */
if (pkt->insn[i].slot == 0) {
bool is_endloop = (pkt->insn[i].opcode == J2_endloop01);
is_endloop |= (pkt->insn[i].opcode == J2_endloop0);
is_endloop |= (pkt->insn[i].opcode == J2_endloop1);
/*
* Make sure it's not endloop since, we're overloading
* slot0 for endloop
*/
if (!is_endloop) {
slot0_found = true;
}
}
/* Is slot1 used? */
if (pkt->insn[i].slot == 1) {
slot1_found = true;
slot1_iidx = i;
}
}
/* Is slot0 empty and slot1 used? */
if ((!slot0_found) && slot1_found) {
/* Then push it to slot0 */
pkt->insn[slot1_iidx].slot = 0;
}
return has_valid_slot_assignment(pkt);
}
/*
* decode_packet
* Decodes packet with given words
* Returns 0 on insufficient words,
* or number of words used on success
*/
int decode_packet(int max_words, const uint32_t *words, Packet *pkt,
bool disas_only)
{
int num_insns = 0;
int words_read = 0;
bool end_of_packet = false;
int new_insns = 0;
int i;
uint32_t encoding32;
/* Initialize */
memset(pkt, 0, sizeof(*pkt));
/* Try to build packet */
while (!end_of_packet && (words_read < max_words)) {
encoding32 = words[words_read];
end_of_packet = is_packet_end(encoding32);
new_insns = decode_insns(&pkt->insn[num_insns], encoding32);
g_assert(new_insns > 0);
/*
* If we saw an extender, mark next word extended so immediate
* decode works
*/
if (pkt->insn[num_insns].opcode == A4_ext) {
pkt->insn[num_insns + 1].extension_valid = true;
}
num_insns += new_insns;
words_read++;
}
pkt->num_insns = num_insns;
if (!end_of_packet) {
/* Ran out of words! */
return 0;
}
pkt->encod_pkt_size_in_bytes = words_read * 4;
pkt->pkt_has_hvx = false;
for (i = 0; i < num_insns; i++) {
pkt->pkt_has_hvx |=
GET_ATTRIB(pkt->insn[i].opcode, A_CVI);
}
/*
* Check for :endloop in the parse bits
* Section 10.6 of the Programmer's Reference describes the encoding
* The end of hardware loop 0 can be encoded with 2 words
* The end of hardware loop 1 needs 3 words
*/
if ((words_read == 2) && (decode_parsebits_is_loopend(words[0]))) {
decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 0);
}
if (words_read >= 3) {
bool has_loop0, has_loop1;
has_loop0 = decode_parsebits_is_loopend(words[0]);
has_loop1 = decode_parsebits_is_loopend(words[1]);
if (has_loop0 && has_loop1) {
decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 10);
} else if (has_loop1) {
decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 1);
} else if (has_loop0) {
decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 0);
}
}
decode_apply_extenders(pkt);
if (!disas_only) {
decode_remove_extenders(pkt);
if (!decode_set_slot_number(pkt)) {
/* Invalid packet */
return 0;
}
}
decode_fill_newvalue_regno(pkt);
if (pkt->pkt_has_hvx) {
mmvec_ext_decode_checks(pkt, disas_only);
}
if (!disas_only) {
decode_shuffle_for_execution(pkt);
decode_split_cmpjump(pkt);
decode_set_insn_attr_fields(pkt);
}
return words_read;
}
/* Used for "-d in_asm" logging */
int disassemble_hexagon(uint32_t *words, int nwords, bfd_vma pc,
GString *buf)
{
Packet pkt;
if (decode_packet(nwords, words, &pkt, true) > 0) {
snprint_a_pkt_disas(buf, &pkt, words, pc);
return pkt.encod_pkt_size_in_bytes;
} else {
g_string_assign(buf, "<invalid>");
return 0;
}
}