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@c Copyright 2006
@c Free Software Foundation, Inc.
@c This is part of the GAS manual.
@c For copying conditions, see the file as.texinfo.
 
@ifset GENERIC
@page
@node AVR-Dependent
@chapter AVR Dependent Features
@end ifset
 
@ifclear GENERIC
@node Machine Dependencies
@chapter AVR Dependent Features
@end ifclear
 
@cindex AVR support
@menu
* AVR Options::              Options
* AVR Syntax::               Syntax
* AVR Opcodes::              Opcodes
@end menu
 
@node AVR Options
@section Options
@cindex AVR options (none)
@cindex options for AVR (none)
 
@table @code
 
@cindex @code{-mmcu=} command line option, AVR
@item -mmcu=@var{mcu}
Specify ATMEL AVR instruction set or MCU type.
 
Instruction set avr1 is for the minimal AVR core, not supported by the C
compiler, only for assembler programs (MCU types: at90s1200,
attiny11, attiny12, attiny15, attiny28).
 
Instruction set avr2 (default) is for the classic AVR core with up to
8K program memory space (MCU types: at90s2313, at90s2323, attiny22,
attiny26, at90s2333, at90s2343, at90s4414, at90s4433, at90s4434,
at90s8515, at90c8534, at90s8535, at86rf401, attiny13, attiny2313,
attiny261, attiny461, attiny861, attiny24, attiny44, attiny84, attiny25,
attiny45, attiny85, attiny43u, attiny48, attiny88).
 
Instruction set avr3 is for the classic AVR core with up to 128K program
memory space (MCU types: atmega103, at43usb320, at43usb355, at76c711,
at90usb82, at90usb162, attiny167).
 
Instruction set avr4 is for the enhanced AVR core with up to 8K program
memory space (MCU types: atmega48, atmega48p,atmega8, atmega88, atmega88p,
atmega8515, atmega8535, atmega8hva, at90pwm1, at90pwm2, at90pwm2b,
at90pwm3, at90pwm3b).
 
Instruction set avr5 is for the enhanced AVR core with up to 128K program
memory space (MCU types: atmega16, atmega161, atmega162, atmega163,
atmega164p, atmega165, atmega165p, atmega168, atmega168p, atmega169,
atmega169p, atmega32, atmega323, atmega324p, atmega325, atmega325p,
atmega328p, atmega329, atmega329p, atmega3250, atmega3250p, atmega3290,
atmega3290p, atmega32hvb, atmega406, atmega64, atmega640, atmega644,
atmega644p, atmega128, atmega1280, atmega1281, atmega1284p, atmega645,
atmega649, atmega6450, atmega6490, atmega16hva, at90can32, at90can64,
at90can128, at90pwm216, at90pwm316, atmega32c1, atmega32m1, atmega32u4,
at90usb646, at90usb647, at90usb1286, at90usb1287, at94k).
 
Instruction set avr6 is for the enhanced AVR core with 256K program
memory space (MCU types: atmega2560, atmega2561).
 
@cindex @code{-mall-opcodes} command line option, AVR
@item -mall-opcodes
Accept all AVR opcodes, even if not supported by @code{-mmcu}.
 
@cindex @code{-mno-skip-bug} command line option, AVR
@item -mno-skip-bug
This option disable warnings for skipping two-word instructions.
 
@cindex @code{-mno-wrap} command line option, AVR
@item -mno-wrap
This option reject @code{rjmp/rcall} instructions with 8K wrap-around.
 
@end table
 
 
@node AVR Syntax
@section Syntax
@menu
* AVR-Chars::                Special Characters
* AVR-Regs::                 Register Names
* AVR-Modifiers::            Relocatable Expression Modifiers
@end menu
 
@node AVR-Chars
@subsection Special Characters
 
@cindex line comment character, AVR
@cindex AVR line comment character
 
The presence of a @samp{;} on a line indicates the start of a comment
that extends to the end of the current line.  If a @samp{#} appears as
the first character of a line, the whole line is treated as a comment.
 
@cindex line separator, AVR
@cindex statement separator, AVR
@cindex AVR line separator
 
The @samp{$} character can be used instead of a newline to separate
statements.
 
@node AVR-Regs
@subsection Register Names
 
@cindex AVR register names
@cindex register names, AVR
 
The AVR has 32 x 8-bit general purpose working registers @samp{r0},
@samp{r1}, ... @samp{r31}.
Six of the 32 registers can be used as three 16-bit indirect address
register pointers for Data Space addressing. One of the these address
pointers can also be used as an address pointer for look up tables in
Flash program memory. These added function registers are the 16-bit
@samp{X}, @samp{Y} and @samp{Z} - registers.
 
@smallexample
X = @r{r26:r27}
Y = @r{r28:r29}
Z = @r{r30:r31}
@end smallexample
 
@node AVR-Modifiers
@subsection Relocatable Expression Modifiers
 
@cindex AVR modifiers
@cindex syntax, AVR
 
The assembler supports several modifiers when using relocatable addresses
in AVR instruction operands.  The general syntax is the following:
 
@smallexample
modifier(relocatable-expression)
@end smallexample
 
@table @code
@cindex symbol modifiers
 
@item lo8
 
This modifier allows you to use bits 0 through 7 of
an address expression as 8 bit relocatable expression.
 
@item hi8
 
This modifier allows you to use bits 7 through 15 of an address expression
as 8 bit relocatable expression.  This is useful with, for example, the
AVR @samp{ldi} instruction and @samp{lo8} modifier.
 
For example
 
@smallexample
ldi r26, lo8(sym+10)
ldi r27, hi8(sym+10)
@end smallexample
 
@item hh8
 
This modifier allows you to use bits 16 through 23 of
an address expression as 8 bit relocatable expression.
Also, can be useful for loading 32 bit constants.
 
@item hlo8
 
Synonym of @samp{hh8}.
 
@item hhi8
 
This modifier allows you to use bits 24 through 31 of
an expression as 8 bit expression. This is useful with, for example, the
AVR @samp{ldi} instruction and @samp{lo8}, @samp{hi8}, @samp{hlo8},
@samp{hhi8}, modifier.
 
For example
 
@smallexample
ldi r26, lo8(285774925)
ldi r27, hi8(285774925)
ldi r28, hlo8(285774925)
ldi r29, hhi8(285774925)
; r29,r28,r27,r26 = 285774925
@end smallexample
 
@item pm_lo8
 
This modifier allows you to use bits 0 through 7 of
an address expression as 8 bit relocatable expression.
This modifier useful for addressing data or code from
Flash/Program memory. The using of @samp{pm_lo8} similar
to @samp{lo8}.
 
@item pm_hi8
 
This modifier allows you to use bits 8 through 15 of
an address expression as 8 bit relocatable expression.
This modifier useful for addressing data or code from
Flash/Program memory.
 
@item pm_hh8
 
This modifier allows you to use bits 15 through 23 of
an address expression as 8 bit relocatable expression.
This modifier useful for addressing data or code from
Flash/Program memory.
 
@end table
 
@node AVR Opcodes
@section Opcodes
 
@cindex AVR opcode summary
@cindex opcode summary, AVR
@cindex mnemonics, AVR
@cindex instruction summary, AVR
For detailed information on the AVR machine instruction set, see
@url{www.atmel.com/products/AVR}.
 
@code{@value{AS}} implements all the standard AVR opcodes.
The following table summarizes the AVR opcodes, and their arguments.
 
@smallexample
@i{Legend:}
   r   @r{any register}
   d   @r{`ldi' register (r16-r31)}
   v   @r{`movw' even register (r0, r2, ..., r28, r30)}
   a   @r{`fmul' register (r16-r23)}
   w   @r{`adiw' register (r24,r26,r28,r30)}
   e   @r{pointer registers (X,Y,Z)}
   b   @r{base pointer register and displacement ([YZ]+disp)}
   z   @r{Z pointer register (for [e]lpm Rd,Z[+])}
   M   @r{immediate value from 0 to 255}
   n   @r{immediate value from 0 to 255 ( n = ~M ). Relocation impossible}
   s   @r{immediate value from 0 to 7}
   P   @r{Port address value from 0 to 63. (in, out)}
   p   @r{Port address value from 0 to 31. (cbi, sbi, sbic, sbis)}
   K   @r{immediate value from 0 to 63 (used in `adiw', `sbiw')}
   i   @r{immediate value}
   l   @r{signed pc relative offset from -64 to 63}
   L   @r{signed pc relative offset from -2048 to 2047}
   h   @r{absolute code address (call, jmp)}
   S   @r{immediate value from 0 to 7 (S = s << 4)}
   ?   @r{use this opcode entry if no parameters, else use next opcode entry}
 
1001010010001000   clc
1001010011011000   clh
1001010011111000   cli
1001010010101000   cln
1001010011001000   cls
1001010011101000   clt
1001010010111000   clv
1001010010011000   clz
1001010000001000   sec
1001010001011000   seh
1001010001111000   sei
1001010000101000   sen
1001010001001000   ses
1001010001101000   set
1001010000111000   sev
1001010000011000   sez
100101001SSS1000   bclr    S
100101000SSS1000   bset    S
1001010100001001   icall
1001010000001001   ijmp
1001010111001000   lpm     ?
1001000ddddd010+   lpm     r,z
1001010111011000   elpm    ?
1001000ddddd011+   elpm    r,z
0000000000000000   nop
1001010100001000   ret
1001010100011000   reti
1001010110001000   sleep
1001010110011000   break
1001010110101000   wdr
1001010111101000   spm
000111rdddddrrrr   adc     r,r
000011rdddddrrrr   add     r,r
001000rdddddrrrr   and     r,r
000101rdddddrrrr   cp      r,r
000001rdddddrrrr   cpc     r,r
000100rdddddrrrr   cpse    r,r
001001rdddddrrrr   eor     r,r
001011rdddddrrrr   mov     r,r
100111rdddddrrrr   mul     r,r
001010rdddddrrrr   or      r,r
000010rdddddrrrr   sbc     r,r
000110rdddddrrrr   sub     r,r
001001rdddddrrrr   clr     r
000011rdddddrrrr   lsl     r
000111rdddddrrrr   rol     r
001000rdddddrrrr   tst     r
0111KKKKddddKKKK   andi    d,M
0111KKKKddddKKKK   cbr     d,n
1110KKKKddddKKKK   ldi     d,M
11101111dddd1111   ser     d
0110KKKKddddKKKK   ori     d,M
0110KKKKddddKKKK   sbr     d,M
0011KKKKddddKKKK   cpi     d,M
0100KKKKddddKKKK   sbci    d,M
0101KKKKddddKKKK   subi    d,M
1111110rrrrr0sss   sbrc    r,s
1111111rrrrr0sss   sbrs    r,s
1111100ddddd0sss   bld     r,s
1111101ddddd0sss   bst     r,s
10110PPdddddPPPP   in      r,P
10111PPrrrrrPPPP   out     P,r
10010110KKddKKKK   adiw    w,K
10010111KKddKKKK   sbiw    w,K
10011000pppppsss   cbi     p,s
10011010pppppsss   sbi     p,s
10011001pppppsss   sbic    p,s
10011011pppppsss   sbis    p,s
111101lllllll000   brcc    l
111100lllllll000   brcs    l
111100lllllll001   breq    l
111101lllllll100   brge    l
111101lllllll101   brhc    l
111100lllllll101   brhs    l
111101lllllll111   brid    l
111100lllllll111   brie    l
111100lllllll000   brlo    l
111100lllllll100   brlt    l
111100lllllll010   brmi    l
111101lllllll001   brne    l
111101lllllll010   brpl    l
111101lllllll000   brsh    l
111101lllllll110   brtc    l
111100lllllll110   brts    l
111101lllllll011   brvc    l
111100lllllll011   brvs    l
111101lllllllsss   brbc    s,l
111100lllllllsss   brbs    s,l
1101LLLLLLLLLLLL   rcall   L
1100LLLLLLLLLLLL   rjmp    L
1001010hhhhh111h   call    h
1001010hhhhh110h   jmp     h
1001010rrrrr0101   asr     r
1001010rrrrr0000   com     r
1001010rrrrr1010   dec     r
1001010rrrrr0011   inc     r
1001010rrrrr0110   lsr     r
1001010rrrrr0001   neg     r
1001000rrrrr1111   pop     r
1001001rrrrr1111   push    r
1001010rrrrr0111   ror     r
1001010rrrrr0010   swap    r
00000001ddddrrrr   movw    v,v
00000010ddddrrrr   muls    d,d
000000110ddd0rrr   mulsu   a,a
000000110ddd1rrr   fmul    a,a
000000111ddd0rrr   fmuls   a,a
000000111ddd1rrr   fmulsu  a,a
1001001ddddd0000   sts     i,r
1001000ddddd0000   lds     r,i
10o0oo0dddddbooo   ldd     r,b
100!000dddddee-+   ld      r,e
10o0oo1rrrrrbooo   std     b,r
100!001rrrrree-+   st      e,r
1001010100011001   eicall
1001010000011001   eijmp
@end smallexample

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[/] [openrisc/] [trunk/] [gnu-src/] [binutils-2.18.50/] [gas/] [doc/] [c-avr.texi] - Blame information for rev 308

Line No.	Rev	Author	Line
1	38	julius	`@c Copyright 2006`
2			`@c Free Software Foundation, Inc.`
3			`@c This is part of the GAS manual.`
4			`@c For copying conditions, see the file as.texinfo.`
5
6			`@ifset GENERIC`
7			`@page`
8			`@node AVR-Dependent`
9			`@chapter AVR Dependent Features`
10			`@end ifset`
11
12			`@ifclear GENERIC`
13			`@node Machine Dependencies`
14			`@chapter AVR Dependent Features`
15			`@end ifclear`
16
17			`@cindex AVR support`
18			`@menu`
19			`* AVR Options:: Options`
20			`* AVR Syntax:: Syntax`
21			`* AVR Opcodes:: Opcodes`
22			`@end menu`
23
24			`@node AVR Options`
25			`@section Options`
26			`@cindex AVR options (none)`
27			`@cindex options for AVR (none)`
28
29			`@table @code`
30
31			`@cindex @code{-mmcu=} command line option, AVR`
32			`@item -mmcu=@var{mcu}`
33			`Specify ATMEL AVR instruction set or MCU type.`
34
35			`Instruction set avr1 is for the minimal AVR core, not supported by the C`
36			`compiler, only for assembler programs (MCU types: at90s1200,`
37			`attiny11, attiny12, attiny15, attiny28).`
38
39			`Instruction set avr2 (default) is for the classic AVR core with up to`
40			`8K program memory space (MCU types: at90s2313, at90s2323, attiny22,`
41			`attiny26, at90s2333, at90s2343, at90s4414, at90s4433, at90s4434,`
42			`at90s8515, at90c8534, at90s8535, at86rf401, attiny13, attiny2313,`
43			`attiny261, attiny461, attiny861, attiny24, attiny44, attiny84, attiny25,`
44			`attiny45, attiny85, attiny43u, attiny48, attiny88).`
45
46			`Instruction set avr3 is for the classic AVR core with up to 128K program`
47			`memory space (MCU types: atmega103, at43usb320, at43usb355, at76c711,`
48			`at90usb82, at90usb162, attiny167).`
49
50			`Instruction set avr4 is for the enhanced AVR core with up to 8K program`
51			`memory space (MCU types: atmega48, atmega48p,atmega8, atmega88, atmega88p,`
52			`atmega8515, atmega8535, atmega8hva, at90pwm1, at90pwm2, at90pwm2b,`
53			`at90pwm3, at90pwm3b).`
54
55			`Instruction set avr5 is for the enhanced AVR core with up to 128K program`
56			`memory space (MCU types: atmega16, atmega161, atmega162, atmega163,`
57			`atmega164p, atmega165, atmega165p, atmega168, atmega168p, atmega169,`
58			`atmega169p, atmega32, atmega323, atmega324p, atmega325, atmega325p,`
59			`atmega328p, atmega329, atmega329p, atmega3250, atmega3250p, atmega3290,`
60			`atmega3290p, atmega32hvb, atmega406, atmega64, atmega640, atmega644,`
61			`atmega644p, atmega128, atmega1280, atmega1281, atmega1284p, atmega645,`
62			`atmega649, atmega6450, atmega6490, atmega16hva, at90can32, at90can64,`
63			`at90can128, at90pwm216, at90pwm316, atmega32c1, atmega32m1, atmega32u4,`
64			`at90usb646, at90usb647, at90usb1286, at90usb1287, at94k).`
65
66			`Instruction set avr6 is for the enhanced AVR core with 256K program`
67			`memory space (MCU types: atmega2560, atmega2561).`
68
69			`@cindex @code{-mall-opcodes} command line option, AVR`
70			`@item -mall-opcodes`
71			`Accept all AVR opcodes, even if not supported by @code{-mmcu}.`
72
73			`@cindex @code{-mno-skip-bug} command line option, AVR`
74			`@item -mno-skip-bug`
75			`This option disable warnings for skipping two-word instructions.`
76
77			`@cindex @code{-mno-wrap} command line option, AVR`
78			`@item -mno-wrap`
79			`This option reject @code{rjmp/rcall} instructions with 8K wrap-around.`
80
81			`@end table`
82
83
84			`@node AVR Syntax`
85			`@section Syntax`
86			`@menu`
87			`* AVR-Chars:: Special Characters`
88			`* AVR-Regs:: Register Names`
89			`* AVR-Modifiers:: Relocatable Expression Modifiers`
90			`@end menu`
91
92			`@node AVR-Chars`
93			`@subsection Special Characters`
94
95			`@cindex line comment character, AVR`
96			`@cindex AVR line comment character`
97
98			`The presence of a @samp{;} on a line indicates the start of a comment`
99			`that extends to the end of the current line. If a @samp{#} appears as`
100			`the first character of a line, the whole line is treated as a comment.`
101
102			`@cindex line separator, AVR`
103			`@cindex statement separator, AVR`
104			`@cindex AVR line separator`
105
106			`The @samp{$} character can be used instead of a newline to separate`
107			`statements.`
108
109			`@node AVR-Regs`
110			`@subsection Register Names`
111
112			`@cindex AVR register names`
113			`@cindex register names, AVR`
114
115			`The AVR has 32 x 8-bit general purpose working registers @samp{r0},`
116			`@samp{r1}, ... @samp{r31}.`
117			`Six of the 32 registers can be used as three 16-bit indirect address`
118			`register pointers for Data Space addressing. One of the these address`
119			`pointers can also be used as an address pointer for look up tables in`
120			`Flash program memory. These added function registers are the 16-bit`
121			`@samp{X}, @samp{Y} and @samp{Z} - registers.`
122
123			`@smallexample`
124			`X = @r{r26:r27}`
125			`Y = @r{r28:r29}`
126			`Z = @r{r30:r31}`
127			`@end smallexample`
128
129			`@node AVR-Modifiers`
130			`@subsection Relocatable Expression Modifiers`
131
132			`@cindex AVR modifiers`
133			`@cindex syntax, AVR`
134
135			`The assembler supports several modifiers when using relocatable addresses`
136			`in AVR instruction operands. The general syntax is the following:`
137
138			`@smallexample`
139			`modifier(relocatable-expression)`
140			`@end smallexample`
141
142			`@table @code`
143			`@cindex symbol modifiers`
144
145			`@item lo8`
146
147			`This modifier allows you to use bits 0 through 7 of`
148			`an address expression as 8 bit relocatable expression.`
149
150			`@item hi8`
151
152			`This modifier allows you to use bits 7 through 15 of an address expression`
153			`as 8 bit relocatable expression. This is useful with, for example, the`
154			`AVR @samp{ldi} instruction and @samp{lo8} modifier.`
155
156			`For example`
157
158			`@smallexample`
159			`ldi r26, lo8(sym+10)`
160			`ldi r27, hi8(sym+10)`
161			`@end smallexample`
162
163			`@item hh8`
164
165			`This modifier allows you to use bits 16 through 23 of`
166			`an address expression as 8 bit relocatable expression.`
167			`Also, can be useful for loading 32 bit constants.`
168
169			`@item hlo8`
170
171			`Synonym of @samp{hh8}.`
172
173			`@item hhi8`
174
175			`This modifier allows you to use bits 24 through 31 of`
176			`an expression as 8 bit expression. This is useful with, for example, the`
177			`AVR @samp{ldi} instruction and @samp{lo8}, @samp{hi8}, @samp{hlo8},`
178			`@samp{hhi8}, modifier.`
179
180			`For example`
181
182			`@smallexample`
183			`ldi r26, lo8(285774925)`
184			`ldi r27, hi8(285774925)`
185			`ldi r28, hlo8(285774925)`
186			`ldi r29, hhi8(285774925)`
187			`; r29,r28,r27,r26 = 285774925`
188			`@end smallexample`
189
190			`@item pm_lo8`
191
192			`This modifier allows you to use bits 0 through 7 of`
193			`an address expression as 8 bit relocatable expression.`
194			`This modifier useful for addressing data or code from`
195			`Flash/Program memory. The using of @samp{pm_lo8} similar`
196			`to @samp{lo8}.`
197
198			`@item pm_hi8`
199
200			`This modifier allows you to use bits 8 through 15 of`
201			`an address expression as 8 bit relocatable expression.`
202			`This modifier useful for addressing data or code from`
203			`Flash/Program memory.`
204
205			`@item pm_hh8`
206
207			`This modifier allows you to use bits 15 through 23 of`
208			`an address expression as 8 bit relocatable expression.`
209			`This modifier useful for addressing data or code from`
210			`Flash/Program memory.`
211
212			`@end table`
213
214			`@node AVR Opcodes`
215			`@section Opcodes`
216
217			`@cindex AVR opcode summary`
218			`@cindex opcode summary, AVR`
219			`@cindex mnemonics, AVR`
220			`@cindex instruction summary, AVR`
221			`For detailed information on the AVR machine instruction set, see`
222			`@url{www.atmel.com/products/AVR}.`
223
224			`@code{@value{AS}} implements all the standard AVR opcodes.`
225			`The following table summarizes the AVR opcodes, and their arguments.`
226
227			`@smallexample`
228			`@i{Legend:}`
229			`r @r{any register}`
230			d @r{`ldi' register (r16-r31)}
231			v @r{`movw' even register (r0, r2, ..., r28, r30)}
232			a @r{`fmul' register (r16-r23)}
233			w @r{`adiw' register (r24,r26,r28,r30)}
234			`e @r{pointer registers (X,Y,Z)}`
235			`b @r{base pointer register and displacement ([YZ]+disp)}`
236			`z @r{Z pointer register (for [e]lpm Rd,Z[+])}`
237			`M @r{immediate value from 0 to 255}`
238			`n @r{immediate value from 0 to 255 ( n = ~M ). Relocation impossible}`
239			`s @r{immediate value from 0 to 7}`
240			`P @r{Port address value from 0 to 63. (in, out)}`
241			`p @r{Port address value from 0 to 31. (cbi, sbi, sbic, sbis)}`
242			K @r{immediate value from 0 to 63 (used in `adiw', `sbiw')}
243			`i @r{immediate value}`
244			`l @r{signed pc relative offset from -64 to 63}`
245			`L @r{signed pc relative offset from -2048 to 2047}`
246			`h @r{absolute code address (call, jmp)}`
247			`S @r{immediate value from 0 to 7 (S = s << 4)}`
248			`? @r{use this opcode entry if no parameters, else use next opcode entry}`
249
250			`1001010010001000 clc`
251			`1001010011011000 clh`
252			`1001010011111000 cli`
253			`1001010010101000 cln`
254			`1001010011001000 cls`
255			`1001010011101000 clt`
256			`1001010010111000 clv`
257			`1001010010011000 clz`
258			`1001010000001000 sec`
259			`1001010001011000 seh`
260			`1001010001111000 sei`
261			`1001010000101000 sen`
262			`1001010001001000 ses`
263			`1001010001101000 set`
264			`1001010000111000 sev`
265			`1001010000011000 sez`
266			`100101001SSS1000 bclr S`
267			`100101000SSS1000 bset S`
268			`1001010100001001 icall`
269			`1001010000001001 ijmp`
270			`1001010111001000 lpm ?`
271			`1001000ddddd010+ lpm r,z`
272			`1001010111011000 elpm ?`
273			`1001000ddddd011+ elpm r,z`
274			`0000000000000000 nop`
275			`1001010100001000 ret`
276			`1001010100011000 reti`
277			`1001010110001000 sleep`
278			`1001010110011000 break`
279			`1001010110101000 wdr`
280			`1001010111101000 spm`
281			`000111rdddddrrrr adc r,r`
282			`000011rdddddrrrr add r,r`
283			`001000rdddddrrrr and r,r`
284			`000101rdddddrrrr cp r,r`
285			`000001rdddddrrrr cpc r,r`
286			`000100rdddddrrrr cpse r,r`
287			`001001rdddddrrrr eor r,r`
288			`001011rdddddrrrr mov r,r`
289			`100111rdddddrrrr mul r,r`
290			`001010rdddddrrrr or r,r`
291			`000010rdddddrrrr sbc r,r`
292			`000110rdddddrrrr sub r,r`
293			`001001rdddddrrrr clr r`
294			`000011rdddddrrrr lsl r`
295			`000111rdddddrrrr rol r`
296			`001000rdddddrrrr tst r`
297			`0111KKKKddddKKKK andi d,M`
298			`0111KKKKddddKKKK cbr d,n`
299			`1110KKKKddddKKKK ldi d,M`
300			`11101111dddd1111 ser d`
301			`0110KKKKddddKKKK ori d,M`
302			`0110KKKKddddKKKK sbr d,M`
303			`0011KKKKddddKKKK cpi d,M`
304			`0100KKKKddddKKKK sbci d,M`
305			`0101KKKKddddKKKK subi d,M`
306			`1111110rrrrr0sss sbrc r,s`
307			`1111111rrrrr0sss sbrs r,s`
308			`1111100ddddd0sss bld r,s`
309			`1111101ddddd0sss bst r,s`
310			`10110PPdddddPPPP in r,P`
311			`10111PPrrrrrPPPP out P,r`
312			`10010110KKddKKKK adiw w,K`
313			`10010111KKddKKKK sbiw w,K`
314			`10011000pppppsss cbi p,s`
315			`10011010pppppsss sbi p,s`
316			`10011001pppppsss sbic p,s`
317			`10011011pppppsss sbis p,s`
318			`111101lllllll000 brcc l`
319			`111100lllllll000 brcs l`
320			`111100lllllll001 breq l`
321			`111101lllllll100 brge l`
322			`111101lllllll101 brhc l`
323			`111100lllllll101 brhs l`
324			`111101lllllll111 brid l`
325			`111100lllllll111 brie l`
326			`111100lllllll000 brlo l`
327			`111100lllllll100 brlt l`
328			`111100lllllll010 brmi l`
329			`111101lllllll001 brne l`
330			`111101lllllll010 brpl l`
331			`111101lllllll000 brsh l`
332			`111101lllllll110 brtc l`
333			`111100lllllll110 brts l`
334			`111101lllllll011 brvc l`
335			`111100lllllll011 brvs l`
336			`111101lllllllsss brbc s,l`
337			`111100lllllllsss brbs s,l`
338			`1101LLLLLLLLLLLL rcall L`
339			`1100LLLLLLLLLLLL rjmp L`
340			`1001010hhhhh111h call h`
341			`1001010hhhhh110h jmp h`
342			`1001010rrrrr0101 asr r`
343			`1001010rrrrr0000 com r`
344			`1001010rrrrr1010 dec r`
345			`1001010rrrrr0011 inc r`
346			`1001010rrrrr0110 lsr r`
347			`1001010rrrrr0001 neg r`
348			`1001000rrrrr1111 pop r`
349			`1001001rrrrr1111 push r`
350			`1001010rrrrr0111 ror r`
351			`1001010rrrrr0010 swap r`
352			`00000001ddddrrrr movw v,v`
353			`00000010ddddrrrr muls d,d`
354			`000000110ddd0rrr mulsu a,a`
355			`000000110ddd1rrr fmul a,a`
356			`000000111ddd0rrr fmuls a,a`
357			`000000111ddd1rrr fmulsu a,a`
358			`1001001ddddd0000 sts i,r`
359			`1001000ddddd0000 lds r,i`
360			`10o0oo0dddddbooo ldd r,b`
361			`100!000dddddee-+ ld r,e`
362			`10o0oo1rrrrrbooo std b,r`
363			`100!001rrrrree-+ st e,r`
364			`1001010100011001 eicall`
365			`1001010000011001 eijmp`
366			`@end smallexample`