qemu/target/avr/insn.decode
Michael Rolnik 46188cabae target/avr: Add instruction translation - MCU Control Instructions
This includes:
    - BREAK
    - NOP
    - SLEEP
    - WDR

Signed-off-by: Michael Rolnik <mrolnik@gmail.com>
Signed-off-by: Richard Henderson <richard.henderson@linaro.org>
Signed-off-by: Aleksandar Markovic <aleksandar.m.mail@gmail.com>
Reviewed-by: Aleksandar Markovic <aleksandar.m.mail@gmail.com>
Signed-off-by: Thomas Huth <huth@tuxfamily.org>
Message-Id: <20200705140315.260514-16-huth@tuxfamily.org>
Signed-off-by: Philippe Mathieu-Daudé <f4bug@amsat.org>
2020-07-11 11:02:05 +02:00

187 lines
6.8 KiB
Text

#
# AVR instruction decode definitions.
#
# Copyright (c) 2019-2020 Michael Rolnik <mrolnik@gmail.com>
#
# This library is free software; you can redistribute it and/or
# modify it under the terms of the GNU Lesser General Public
# License as published by the Free Software Foundation; either
# version 2.1 of the License, or (at your option) any later version.
#
# This library 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
# Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public
# License along with this library; if not, see <http://www.gnu.org/licenses/>.
#
#
# regs_16_31_by_one = [16 .. 31]
# regs_16_23_by_one = [16 .. 23]
# regs_24_30_by_two = [24, 26, 28, 30]
# regs_00_30_by_two = [0, 2, 4, 6, 8, .. 30]
%rd 4:5
%rr 9:1 0:4
%rd_a 4:4 !function=to_regs_16_31_by_one
%rd_b 4:3 !function=to_regs_16_23_by_one
%rd_c 4:2 !function=to_regs_24_30_by_two
%rr_a 0:4 !function=to_regs_16_31_by_one
%rr_b 0:3 !function=to_regs_16_23_by_one
%imm6 6:2 0:4
%imm8 8:4 0:4
%io_imm 9:2 0:4
%ldst_d_imm 13:1 10:2 0:3
&rd_rr rd rr
&rd_imm rd imm
@op_rd_rr .... .. . ..... .... &rd_rr rd=%rd rr=%rr
@op_rd_imm6 .... .... .. .. .... &rd_imm rd=%rd_c imm=%imm6
@op_rd_imm8 .... .... .... .... &rd_imm rd=%rd_a imm=%imm8
@fmul .... .... . ... . ... &rd_rr rd=%rd_b rr=%rr_b
#
# Arithmetic Instructions
#
ADD 0000 11 . ..... .... @op_rd_rr
ADC 0001 11 . ..... .... @op_rd_rr
ADIW 1001 0110 .. .. .... @op_rd_imm6
SUB 0001 10 . ..... .... @op_rd_rr
SUBI 0101 .... .... .... @op_rd_imm8
SBC 0000 10 . ..... .... @op_rd_rr
SBCI 0100 .... .... .... @op_rd_imm8
SBIW 1001 0111 .. .. .... @op_rd_imm6
AND 0010 00 . ..... .... @op_rd_rr
ANDI 0111 .... .... .... @op_rd_imm8
OR 0010 10 . ..... .... @op_rd_rr
ORI 0110 .... .... .... @op_rd_imm8
EOR 0010 01 . ..... .... @op_rd_rr
COM 1001 010 rd:5 0000
NEG 1001 010 rd:5 0001
INC 1001 010 rd:5 0011
DEC 1001 010 rd:5 1010
MUL 1001 11 . ..... .... @op_rd_rr
MULS 0000 0010 .... .... &rd_rr rd=%rd_a rr=%rr_a
MULSU 0000 0011 0 ... 0 ... @fmul
FMUL 0000 0011 0 ... 1 ... @fmul
FMULS 0000 0011 1 ... 0 ... @fmul
FMULSU 0000 0011 1 ... 1 ... @fmul
DES 1001 0100 imm:4 1011
#
# Branch Instructions
#
# The 22-bit immediate is partially in the opcode word,
# and partially in the next. Use append_16 to build the
# complete 22-bit value.
%imm_call 4:5 0:1 !function=append_16
@op_bit .... .... . bit:3 ....
@op_bit_imm .... .. imm:s7 bit:3
RJMP 1100 imm:s12
IJMP 1001 0100 0000 1001
EIJMP 1001 0100 0001 1001
JMP 1001 010 ..... 110 . imm=%imm_call
RCALL 1101 imm:s12
ICALL 1001 0101 0000 1001
EICALL 1001 0101 0001 1001
CALL 1001 010 ..... 111 . imm=%imm_call
RET 1001 0101 0000 1000
RETI 1001 0101 0001 1000
CPSE 0001 00 . ..... .... @op_rd_rr
CP 0001 01 . ..... .... @op_rd_rr
CPC 0000 01 . ..... .... @op_rd_rr
CPI 0011 .... .... .... @op_rd_imm8
SBRC 1111 110 rr:5 0 bit:3
SBRS 1111 111 rr:5 0 bit:3
SBIC 1001 1001 reg:5 bit:3
SBIS 1001 1011 reg:5 bit:3
BRBS 1111 00 ....... ... @op_bit_imm
BRBC 1111 01 ....... ... @op_bit_imm
#
# Data Transfer Instructions
#
%rd_d 4:4 !function=to_regs_00_30_by_two
%rr_d 0:4 !function=to_regs_00_30_by_two
@io_rd_imm .... . .. ..... .... &rd_imm rd=%rd imm=%io_imm
@ldst_d .. . . .. . rd:5 . ... &rd_imm imm=%ldst_d_imm
# The 16-bit immediate is completely in the next word.
# Fields cannot be defined with no bits, so we cannot play
# the same trick and append to a zero-bit value.
# Defer reading the immediate until trans_{LDS,STS}.
@ldst_s .... ... rd:5 .... imm=0
MOV 0010 11 . ..... .... @op_rd_rr
MOVW 0000 0001 .... .... &rd_rr rd=%rd_d rr=%rr_d
LDI 1110 .... .... .... @op_rd_imm8
LDS 1001 000 ..... 0000 @ldst_s
LDX1 1001 000 rd:5 1100
LDX2 1001 000 rd:5 1101
LDX3 1001 000 rd:5 1110
LDY2 1001 000 rd:5 1001
LDY3 1001 000 rd:5 1010
LDZ2 1001 000 rd:5 0001
LDZ3 1001 000 rd:5 0010
LDDY 10 . 0 .. 0 ..... 1 ... @ldst_d
LDDZ 10 . 0 .. 0 ..... 0 ... @ldst_d
STS 1001 001 ..... 0000 @ldst_s
STX1 1001 001 rr:5 1100
STX2 1001 001 rr:5 1101
STX3 1001 001 rr:5 1110
STY2 1001 001 rd:5 1001
STY3 1001 001 rd:5 1010
STZ2 1001 001 rd:5 0001
STZ3 1001 001 rd:5 0010
STDY 10 . 0 .. 1 ..... 1 ... @ldst_d
STDZ 10 . 0 .. 1 ..... 0 ... @ldst_d
LPM1 1001 0101 1100 1000
LPM2 1001 000 rd:5 0100
LPMX 1001 000 rd:5 0101
ELPM1 1001 0101 1101 1000
ELPM2 1001 000 rd:5 0110
ELPMX 1001 000 rd:5 0111
SPM 1001 0101 1110 1000
SPMX 1001 0101 1111 1000
IN 1011 0 .. ..... .... @io_rd_imm
OUT 1011 1 .. ..... .... @io_rd_imm
PUSH 1001 001 rd:5 1111
POP 1001 000 rd:5 1111
XCH 1001 001 rd:5 0100
LAC 1001 001 rd:5 0110
LAS 1001 001 rd:5 0101
LAT 1001 001 rd:5 0111
#
# Bit and Bit-test Instructions
#
LSR 1001 010 rd:5 0110
ROR 1001 010 rd:5 0111
ASR 1001 010 rd:5 0101
SWAP 1001 010 rd:5 0010
SBI 1001 1010 reg:5 bit:3
CBI 1001 1000 reg:5 bit:3
BST 1111 101 rd:5 0 bit:3
BLD 1111 100 rd:5 0 bit:3
BSET 1001 0100 0 bit:3 1000
BCLR 1001 0100 1 bit:3 1000
#
# MCU Control Instructions
#
BREAK 1001 0101 1001 1000
NOP 0000 0000 0000 0000
SLEEP 1001 0101 1000 1000
WDR 1001 0101 1010 1000