Dalvik Instruction Formats

Dalvik VM Instruction Formats

Copyright © 2007 The Android Open Source Project

Introduction and Overview

This document lists the instruction formats used by Dalvik bytecode and is meant to be used in conjunction with the bytecode reference document.

Bitwise descriptions

The first column in the format table lists the bitwise layout of the format. It consists of one or more space-separated "words" each of which describes a 16-bit code unit. Each character in a word represents four bits, read from high bits to low, with vertical bars ("|") interspersed to aid in reading. Uppercase letters in sequence from "A" are used to indicate fields within the format (which then get defined further by the syntax column). The term "op" is used to indicate the position of the eight-bit opcode within the format. A slashed zero ("Ø") is used to indicate that all bits should be zero in the indicated position.
For example, the format "B|A|op CCCC" indicates that the format consists of two 16-bit code units. The first word consists of the opcode in the low eight bits and a pair of four-bit values in the high eight bits; and the second word consists of a single 16-bit value.

Format IDs

The second column in the format table indicates the short identifier for the format, which is used in other documents and in code to identify the format.
Format IDs consist of three characters, two digits followed by a letter. The first digit indicates the number of 16-bit code units in the format. The second digit indicates the maximum number of registers that the format contains (maximum, since some formats can accomodate a variable number of registers), with the special designation "r" indicating that a range of registers is encoded. The final letter semi-mnemonically indicates the type of any extra data encoded by the format. For example, format "21t" is of length two, contains one register reference, and additionally contains a branch target.
Suggested static linking formats have an additional "s" suffix, making them four characters total.
The full list of typecode letters are as follows. Note that some forms have different sizes, depending on the format:
MnemonicBit SizesMeaning
b8immediate signed byte
c16, 32constant pool index
f16interface constants (only used in statically linked formats)
h16immediate signed hat (high-order bits of a 32- or 64-bit value; low-order bits are all 0)
i32immediate signed int, or 32-bit float
l64immediate signed long, or 64-bit double
m16method constants (only used in statically linked formats)
n4immediate signed nibble
s16immediate signed short
t8, 16, 32branch target
x0no additional data

Syntax

The third column of the format table indicates the human-oriented syntax for instructions which use the indicated format. Each instruction starts with the named opcode and is optionally followed by one or more arguments, themselves separated with commas.
Wherever an argument refers to a field from the first column, the letter for that field is indicated in the syntax, repeated once for each four bits of the field. For example, an eight-bit field labeled "BB" in the first column would also be labeled "BB" in the syntax column.
Arguments which name a register have the form "vX". The prefix "v" was chosen instead of the more common "r" exactly to avoid conflicting with (non-virtual) architectures on which a Dalvik virtual machine might be implemented which themselves use the prefix "r" for their registers. (That is, this decision makes it possible to talk about both virtual and real registers together without the need for circumlocution.)
Arguments which indicate a literal value have the form "#+X". Some formats indicate literals that only have non-zero bits in their high-order bits; for these, the zeroes are represented explicitly in the syntax, even though they do not appear in the bitwise representation.
Arguments which indicate a relative instruction address offset have the form "+X".
Arguments which indicate a literal constant pool index have the form "kind@X", where "kind" indicates which constant pool is being referred to. Each opcode that uses such a format explicitly allows only one kind of constant; see the opcode reference to figure out the correspondence. The four kinds of constant pool are "string" (string pool index), "type" (type pool index), "field" (field pool index), and "meth" (method pool index).
Similar to the representation of constant pool indices, there are also suggested (optional) forms that indicate prelinked offsets or indices. These prelinked values include "vtaboff" (vtable offset), "fieldoff" (field offset), and "iface" (interface pool index).
In the cases where a format value isn't explictly part of the syntax but instead picks a variant, each variant is listed with the prefix "[X=N]" (e.g., "[B=2]") to indicate the correspondence.

The Formats

FormatIDSyntaxNotable Opcodes Covered
ØØ|op10xop 
B|A|op12xop vA, vB 
11nop vA, #+B 
AA|op11xop vAA 
10top +AAgoto
ØØ|op AAAA20top +AAAAgoto/16
AA|op BBBB22xop vAA, vBBBB 
21top vAA, +BBBB 
21sop vAA, #+BBBB 
21hop vAA, #+BBBB0000
op vAA, #+BBBB000000000000
 
21cop vAA, type@BBBB
op vAA, field@BBBB
op vAA, string@BBBB
check-cast
const-class
const-string
AA|op CC|BB23xop vAA, vBB, vCC 
22bop vAA, vBB, #+CC 
B|A|op CCCC22top vA, vB, +CCCC 
22sop vA, vB, #+CCCC 
22cop vA, vB, type@CCCC
op vA, vB, field@CCCC
instance-of
22csop vA, vB, fieldoff@CCCC(suggested format for statically linked field access instructions of format 22c)
ØØ|op AAAAlo AAAAhi30top +AAAAAAAAgoto/32
ØØ|op AAAA BBBB32xop vAAAA, vBBBB 
AA|op BBBBlo BBBBhi31iop vAA, #+BBBBBBBB 
31top vAA, +BBBBBBBB 
31cop vAA, string@BBBBBBBBconst-string/jumbo
B|A|op CCCC G|F|E|D35c[B=5op {vD, vE, vF, vG, vA}, meth@CCCC
[B=5op {vD, vE, vF, vG, vA}, type@CCCC
[B=4op {vD, vE, vF, vG}, kind@CCCC
[B=3op {vD, vE, vF}, kind@CCCC
[B=2op {vD, vE}, kind@CCCC
[B=1op {vD}, kind@CCCC
[B=0op {}, kind@CCCC
 
B|A|op CCCC G|F|E|D35ms[B=5op {vD, vE, vF, vG, vA}, vtaboff@CCCC
[B=4op {vD, vE, vF, vG}, vtaboff@CCCC
[B=3op {vD, vE, vF}, vtaboff@CCCC
[B=2op {vD, vE}, vtaboff@CCCC
[B=1op {vD}, vtaboff@CCCC
(suggested format for statically linkedinvoke-virtual and invoke-superinstructions of format 35c)
B|A|op DDCC H|G|F|E35fs[B=5op {vE, vF, vG, vH, vA}, vtaboff@CC, iface@DD
[B=4op {vE, vF, vG, vH}, vtaboff@CC, iface@DD
[B=3op {vE, vF, vG}, vtaboff@CC, iface@DD
[B=2op {vE, vF}, vtaboff@CC, iface@DD
[B=1op {vE}, vtaboff@CC, iface@DD
(suggested format for statically linkedinvoke-interface instructions of format 35c)
AA|op BBBB CCCC3rcop {vCCCC .. vNNNN}, meth@BBBB
op {vCCCC .. vNNNN}, type@BBBB
(where NNNN = CCCC+AA-1, that is A determines the count 0..255, and C determines the first register)
 
AA|op BBBB CCCC3rmsop {vCCCC .. vNNNN}, vtaboff@BBBB
(where NNNN = CCCC+AA-1, that is A determines the count 0..255, and C determines the first register)
(suggested format for statically linkedinvoke-virtual and invoke-superinstructions of format 3rc)
AA|op CCBB DDDD3rfsop {vDDDD .. vNNNN}, vtaboff@BB, iface@CC
(where NNNN = DDDD+AA-1, that is A determines the count 0..255, and D determines the first register)
(suggested format for statically linkedinvoke-interface instructions of format3rc)
AA|op BBBBlo BBBB BBBB BBBBhi51lop vAA, #+BBBBBBBBBBBBBBBBconst-wide

Dalvik opcodes

Dalvik opcodes

Author: Gabor Paller

Vx values in the table denote a Dalvik register. Depending on the instruction, 16, 256 or 64k registers can be accessed. Operations on long and double values use two registers, e.g. a double value addressed in the V0 register occupies the V0 and V1 registers.

Boolean values are stored as 1 for true and 0 for false. Operations on booleans are translated into integer operations.

All the examples are in hig-endian format, e.g. 0F00 0A00 is coded as
 0F, 00, 0A, 00 sequence.

Note there are no explanation/example at some instructions. This means that I have not seen that instruction "in the wild" and its presence/name is only known from Android opcode constant list.

Opcode (hex)Opcode nameExplanationExample
00nopNo operation0000 - nop 
01move vx,vyMoves the content of vy into vx. Both registers must be in the first 256 register range.0110 - move v0, v1
Moves v1 into v0.
02move/from16 vx,vyMoves the content of vy into vx. vy may be in the 64k register range while vx is one of the first 256 registers.0200 1900 - move/from16 v0, v25
Moves v25 into v0.
03move/16

04move-wide 

05move-wide/from16 vx,vyMoves a long/double value from vy to vx. vy may be in the 64k register range while wx is one of the first 256 registers.0516 0000 - move-wide/from16 v22, v0
Moves v0 into v22.
06move-wide/16

07move-object vx,vyMoves the object reference from vy to vx.0781 - move-object v1, v8
Moves the object reference in v8 to v1.
08move-object/from16 vx,vyMoves the object reference from vy to vx, vy can address 64k registers and vx can address 256 registers.0801 1500 - move-object/from16 v1, v21
Move the object reference in v21 to v1.
09move-object/16

0Amove-result vxMove the result value of the previous method invocation into vx.0A00 - move-result v0
Move the return value of a previous method invocation into v0.
0Bmove-result-wide vxMove the long/double result value of the previous method invocation into vx,vx+1.0B02 - move-result-wide v2
Move the long/double result value of the previous method invocation into v2,v3.
0Cmove-result-object vxMove the result object reference of the previous method invocation into vx.0C00 - move-result-object v0
0Dmove-exception vxMove the exception object reference thrown during a method invocation into vx. 0D19 - move-exception v25
0Ereturn-voidReturn without a return value0E00 - return-void
0Freturn vxReturn with vx return value0F00 - return v0
Returns with return value in v0.
10return-wide vxReturn with double/long result in vx,vx+1.1000 - return-wide v0
Returns with a double/long value in v0,v1.
11return-object vxReturn with vx object reference value.1100 - return-object v0
Returns with object reference value in v0
12const/4 vx,lit4Puts the 4 bit constant into vx1221 - const/4 v1, #int2
Moves literal 2 into v1. The destination register is in the lower 4 bit in the second byte, the literal 2 is in the higher 4 bit.
13const/16 vx,lit16Puts the 16 bit constant into vx1300 0A00 - const/16 v0, #int 10
Puts the literal constant of 10 into v0.
14const vx, lit32Puts the integer constant into vx1400 4E61 BC00 - const v0, #12345678 // #00BC614E
Moves literal 12345678 into v0.
15const/high16 v0, lit16Puts the 16 bit constant into the topmost bits of the register. Used to initialize float values.1500 2041 - const/high16 v0, #float 10.0 // #41200000
Moves the floating literal of 10.0 into v0. The 16 bit literal in the instruction carries the top 16 bits of the floating point number.
16const-wide/16 vx, lit16Puts the integer constant into vx and vx+1 registers, expanding the integer constant into a long constant..1600 0A00 - const-wide/16 v0, #long 10
Moves literal 10 into v0 and v1 registers.
17const-wide/32 vx, lit32Puts the 32 bit constant into vx and vx+1 registers, expanding the integer constant into a long constant.1702 4e61 bc00 - const-wide/32 v2, #long 12345678 // #00bc614e
Puts #12345678 into v2 and v3 registers.
18const-wide vx, lit64Puts the 64 bit constant into vx and vx+1 registers.1802 874b 6b5d 54dc 2b00- const-wide v2, #long 12345678901234567 // #002bdc545d6b4b87
Puts #12345678901234567 into v2 and v3 registers.
19const-wide/high16 vx,lit16Puts the 16 bit constant into the highest 16 bit of vx and vx+1 registers. Used to initialize double values.1900 2440 - const-wide/high16 v0, #double 10.0 // #402400000
Puts the double constant of 10.0 into v0 register.
1Aconst-string vx,string_idPuts reference to a string constant identified by string_id into vx.1A08 0000 - const-string v8, "" // string@0000
Puts reference to string@0000 (entry #0 in the string table) into v8.
1Bconst-string-jumbo

1Cconst-class vx,type_idMoves the class object of a class identified by type_id (e.g. Object.class) into vx.1C00 0100 - const-class v0, Test3 // type@0001
Moves reference to Test3.class (entry#1 in the type id table) into 
1Dmonitor-enter vxObtains the monitor of the object referenced by vx.1D03 - monitor-enter v3
Obtains the monitor of the object referenced by v3.
1Emonitor-exitReleases the monitor of the object referenced by vx.1E03 - monitor-exit v3
Releases the monitor of the object referenced by v3.
1Fcheck-cast vx, type_idChecks whether the object reference in vx can be cast to an instance of a class referenced by type_id. Throws ClassCastException if the cast is not possible, continues execution otherwise.1F04 0100 - check-cast v4, Test3 // type@0001
Checks whether the object reference in v4 can be cast to type@0001 (entry #1 in the type id table)
20instance-of vx,vy,type_idChecks whether vy is instance of a class identified by type_id. Sets vx non-zero if it is, 0 otherwise.2040 0100 - instance-of v0, v4, Test3 // type@0001
Checks whether the object reference in v4 is an instance of type@0001 (entry #1 in the type id table). Sets v0 to non-zero if v4 is instance of Test3, 0 otherwise.
21array-length vx,vyCalculates the number of elements of the array referenced by vy and puts the length value into vx.2111 - array-length v1, v1
Calculates the number of elements of the array referenced by v1 and puts the result into v1.
22new-instance vx,typeInstantiates an object type and puts the reference of the newly created instance into vx.2200 1500 - new-instance v0, java.io.FileInputStream // type@0015
Instantiates type@0015 (entry #15H in the type table) and puts its reference into v0.
23new-array vx,vy,type_idGenerates a new array of type_id type and vy element size and puts the reference to the array into vx.2312 2500 - new-array v2, v1, char[] // type@0025
Generates a new array of type@0025 type and v1 size and puts the reference to the new array into v2.
24filled-new-array {parameters},type_idGenerates a new array of type_id and fills it with the parameters5. Reference to the newly generated array can be obtained by a move-result-object instruction, immediately following the filled-new-array instruction.2420 530D 0000 - filled-new-array {v0,v0},[I // type@0D53
Generates a new array of type@0D53. The array's size will be 2 and both elements will be filled with the contents of v0 register.
25filled-new-array-range {vx..vy},type_idGenerates a new array of type_id and fills it with a range of parameters. Reference to the newly generated array can be obtained by a move-result-object instruction, immediately following the filled-new-array instruction.2503 0600 1300 - filled-new-array/range {v19..v21}, [B // type@0006
Generates a new array of type@0D53. The array's size will be 3 and the elements will be filled using the v19,v20 and v21 registers4.
26fill-array-data vx,array_data_offsetFills the array referenced by vx with the static data. The location of the static data is the sum of  the position of the current instruction and the offset2606 2500 0000 - fill-array-data v6, 00e6 // +0025
Fills the array referenced by v0 with the static data at current instruction+25H words location. The offset is expressed as a 32-bit number. The static data is stored in the following format:
0003 // Table type: static array data
0400 // Byte per array element (in this case, 4 byte integers)
0300 0000 // Number of elements in the table
0100 0000  // Element #0: integer 1
0200 0000 // Element #1: integer 2
0300 0000 // Element #2: integer3
27throw vxThrows an exception object. The reference of the exception object is in vx.2700 - throw v0
Throws an exception. The exception object reference is in v0.
28goto targetUnconditional jump by short offset228F0 - goto 0005 // -0010
Jumps to current position-16 words (hex 10). 0005 is the label of the target instruction.
29goto/16 targetUnconditional jump by 16 bit offset2.2900 0FFE - goto/16 002f // -01f1
Jumps to the current position-1F1H words. 002F is the label of the target instruction.
2Agoto/32 target

2Bpacked-switch vx,tableImplements a switch statement where the case constants are close to each other. The instruction uses an index table. vx indexes into this table to find the offset of the instruction for a particular case. If vx falls out of the index table, the execution continues on the next instruction (default case).2B02 0C00 0000 - packed-switch v2, 000c // +000c
Execute a packed switch according to the switch argument in v2. The position of the index table is at current instruction+0CH words. The table looks like the following:
0001 // Table type: packed switch table
0300 // number of elements
0000 0000 // element base
0500 0000  0: 00000005 // case 0: +00000005
0700 0000  1: 00000007 // case 1: +00000007
0900 0000  2: 00000009 // case 2: +00000009
2Csparse-switch vx,tableImplements a switch statement with sparse case table. The instruction uses a lookup table with case constants and offsets for each case constant. If there is no match in the table, execution continues on the next instruction (default case).2C02 0c00 0000 - sparse-switch v2, 000c // +000c
Execute a sparse switch according to the switch argument in v2. The position of the lookup table is at current instruction+0CH words. The table looks like the following.
0002 // Table type: sparse switch table
0300 // number of elements
9cff ffff // first case: -100
fa00 0000 // second case constant: 250
e803 0000 // third case constant: 1000
0500 0000 // offset for the first case constant: +5
0700 0000 // offset for the second case constant: +7
0900 0000 // offset for the third case constant: +9
2Dcmpl-floatCompares the float values in vy and vz and sets the integer value in vx accordingly32D00 0607 - cmpl-float v0, v6, v7
Compares the float values in v6 and v7 then sets v0 accordingly. NaN bias is less-than, the instruction will return -1 if any of the parameters is NaN.
2Ecmpg-float vx, vy, vzCompares the float values in vy and vz and sets the integer value in vx accordingly3.2E00 0607 - cmpg-float v0, v6, v7
Compares the float values in v6 and v7 then sets v0 accordingly. NaN bias is greater-than, the instruction will return 1 if any of the parameters is NaN.
2Fcmpl-double vx,vy,vzCompares the double values in vy and vz2 and sets the integer value in vx accordingly3.2F19 0608 - cmpl-double v25, v6, v8
Compares the double values in v6,v7 and v8,v9 and sets v25 accordingly. NaN bias is less-than, the instruction will return -1 if any of the parameters is NaN.
30cmpg-double vx, vy, vzCompares the double values in vy and vz2 and sets the integer value in vx accordingly3.3000 080A - cmpg-double v0, v8, v10
Compares the double values in v8,v9 and v10,v11 then sets v0 accordingly. NaN bias is greater-than, the instruction will return 1 if any of the parameters is NaN.
31cmp-long vx, vy, vzCompares the long values in vy and vz and sets the integer value in vx accordingly3.3100 0204 - cmp-long v0, v2, v4
Compares the long values in v2 and v4 then sets v0 accordingly.
32if-eq vx,vy,targetJumps to target if vx==vy2. vx and vy are integer values.32b3 6600 - if-eq v3, v11, 0080 // +0066
Jumps to the current position+66H words if v3==v11. 0080 is the label of the target instruction.
33if-ne vx,vy,targetJumps to target if vx!=vy2. vx and vy are integer values.33A3 1000 - if-ne v3, v10, 002c // +0010
Jumps to the current position+10H words if v3!=v10. 002c is the label of the target instruction.
34if-lt vx,vy,targetJumps to target is vx<vy2. vx and vy are integer values.3432 CBFF - if-lt v2, v3, 0023 // -0035
Jumps to the current position-35H words if v2<v3. 0023 is the label of the target instruction.
35if-ge vx, vy,targetJumps to target if vx>=vy2. vx and vy are integer values.3510 1B00 - if-ge v0, v1, 002b // +001b
Jumps to the current position+1BH words if v0>=v1. 002b is the label of the target instruction.
36if-gt vx,vy,targetJumps to target if vx>vy2. vx and vy are integer values.3610 1B00 - if-ge v0, v1, 002b // +001b
Jumps to the current position+1BH words if v0>v1. 002b is the label of the target instruction.
37if-le vx,vy,targetJumps to target if vx<=vy2. vx and vy are integer values.3756 0B00 - if-le v6, v5, 0144 // +000b
Jumps to the current position+0BH words if v6<=v5. 0144 is the label of the target instruction.
38if-eqz vx,targetJumps to target if vx==02. vx is an integer value.3802 1900 - if-eqz v2, 0038 // +0019
Jumps to the current position+19H words if v2==0. 0038 is the label of the target instruction.
39if-nez vx,targetChecks vx and jumps if vx is nonzero23902 1200 - if-nez v2, 0014 // +0012
Jumps to current position+18 words (hex 12) if v2 is nonzero. 0014 is the label of the target instruction.
3Aif-ltz vx,targetChecks vx and jumps if vx<02.3A00 1600 - if-ltz v0, 002d // +0016
Jumps to the current position+16H words if v0<0. 002d is the label of the target instruction.
3Bif-gez vx,targetChecks vx and jumps if vx>=02.3B00 1600 - if-gez v0, 002d // +0016
Jumps to the current position+16H words if v0 >=0. 002d is the label of the target instruction.
3Cif-gtz vx,targetChecks vx and jumps if vx>02.3C00 1D00 - if-gtz v0, 004a // +001d
Jumps to the current position+1DH words if v0>0. 004A is the label of the target instruction.
3Dif-lez vx,targetChecks vx and jumps if vx<=02.3D00 1D00 - if-lez v0, 004a // +001d
Jumps to the current position+1DH words if v0<=0. 004A is the label of the target instruction.
3Eunused_3E

3Funused_3F

40unused_40

41unused_41

42unused_42

43unused_43

44aget vx,vy,vzGets an integer value of an object reference array into vx. The array is referenced by vy and is indexed by vz.4407 0306 - aget v7, v3, v6
Gets an integer array element. The array is referenced by v3 and the element is indexed by v6. The element will be put into v7.
45aget-wide vx,vy,vzGets a long/double value of long/double array into vx,vx+1. The array is referenced by vy and is indexed by vz.4505 0104 - aget-wide v5, v1, v4
Gets a long/double array element. The array is referenced by v1 and the element is indexed by v4. The element will be put into v5,v6.
46aget-object vx,vy,vzGets an object reference value of an object reference array into vx. The array is referenced by vy and is indexed by vz.4602 0200 - aget-object v2, v2, v0
Gets an object reference array element. The array is referenced by v2 and the element is indexed by v0. The element will be put into v2.
47aget-boolean vx,vy,vzGets a boolean value of a boolean array into vx. The array is referenced by vy and is indexed by vz.4700 0001 - aget-boolean v0, v0, v1
Gets a boolean array element. The array is referenced by v0 and the element is indexed by v1. The element will be put into v0.
48aget-byte vx,vy,vzGets a byte value of a byte array into vx. The array is referenced by vy and is indexed by vz.4800 0001 - aget-byte v0, v0, v1
Gets a byte array element. The array is referenced by v0 and the element is indexed by v1. The element will be put into v0.
49aget-char vx, vy,vzGets a char value  of a character array into vx. The element is indexed by vz, the array object is referenced by vy4905 0003 - aget-char v5, v0, v3
Gets a character array element. The array is referenced by v0 and the element is indexed by v3. The element will be put into v5.
4Aaget-short vx,vy,vzGets a short value  of a short array into vx. The element is indexed by vz, the array object is referenced by vy.4A00 0001 - aget-short v0, v0, v1
Gets a short array element. The array is referenced by v0 and the element is indexed by v1. The element will be put into v0.
4Baput vx,vy,vzPuts the integer value in vx into an element of an integer array. The element is indexed by vz, the array object is referenced by vy.4B00 0305 - aput v0, v3, v5
Puts the integer value in v2 into an integer array referenced by v0. The target array element is indexed by v1.
4Caput-wide vx,vy,vzPuts the double/long value in vx,vx+1 into a double/long array. The array is referenced by vy, the element is indexed by vz.4C05 0104 - aput-wide v5, v1, v4
Puts the double/long value in v5,v6 into a double/long array referenced by v1. The target array element is indexed by v4.
4Daput-object vx,vy,vzPuts the object reference value in vx into an element of an object reference array. The element is indexed by vz, the array object is referenced by vy.4D02 0100 - aput-object v2, v1, v0
Puts the object reference value in v2 into an object reference array referenced by v0. The target array element is indexed by v1.
4Eaput-boolean vx,vy,vzPuts the boolean value in vx into an element of a boolean array. The element is indexed by vz, the array object is referenced by vy.4E01 0002 - aput-boolean v1, v0, v2
Puts the boolean value in v1 into an object reference array referenced by v0. The target array element is indexed by v2.
4Faput-byte vx,vy,vzPuts the byte value in vx into an element of a byte array. The element is indexed by vz, the array object is referenced by vy.4F02 0001 - aput-byte v2, v0, v1
Puts the boolean value in v2 into a byte array referenced by v0. The target array element is indexed by v1.
50aput-char vx,vy,vzPuts the char value in vx into an element of a character array. The element is indexed by vz, the array object is referenced by vy.5003 0001 - aput-char v3, v0, v1
Puts the character value in v3 into a character array referenced by v0. The target array element is indexed by v1.
51aput-short vx,vy,vzPuts the short value in vx into an element of a short array. The element is indexed by vz, the array object is referenced by vy.5102 0001 - aput-short v2, v0, v1
Puts the short value in v2 into a character array referenced by v0. The target array element is indexed by v1.
52iget vx, vy, field_idReads an instance field into vx. The instance is referenced by vy.5210 0300 - iget v0, v1, Test2.i6:I // field@0003
Reads field@0003 into v0 (entry #3 in the field id table). The instance is referenced by v1.
53iget-wide vx,vy,field_idReads an instance field into vx1. The instance is referenced by vy.5320 0400 - iget-wide v0, v2, Test2.l0:J // field@0004
Reads field@0004 into v0 and v1 registers (entry #4 in the field id table). The instance is referenced by v2.
54iget-object vx,vy,field_idReads an object reference instance field into vx. The instance is referenced by vy.iget-object v1, v2, LineReader.fis:Ljava/io/FileInputStream; // field@0002
Reads field@0002 into v1  (entry #2 in the field id table). The instance is referenced by v2.
55iget-boolean vx,vy,field_idReads a boolean instance field into vx. The instance is referenced by vy.55FC 0000 - iget-boolean v12, v15, Test2.b0:Z // field@0000
Reads the boolean field@0000 into v12 register (entry #0 in the field id table). The instance is referenced by v15.
56iget-byte vx,vy,field_idReads a byte instance field into vx. The instance is referenced by vy.5632 0100 - iget-byte v2, v3, Test3.bi1:B // field@0001
Reads the char field@0001 into v2 register (entry #1 in the field id table). The instance is referenced by v3.
57iget-char vx,vy,field_idReads a char instance field into vx. The instance is referenced by vy.5720 0300 - iget-char v0, v2, Test3.ci1:C // field@0003
Reads the char field@0003 into v0 register (entry #3 in the field id table). The instance is referenced by v2.
58iget-short vx,vy,field_idReads a short instance field into vx. The instance is referenced by vy.5830 0800 - iget-short v0, v3, Test3.si1:S // field@0008
Reads the short field@0008 into v0 register (entry #8 in the field id table). The instance is referenced by v3.
59iput vx,vy, field_idPuts vx into an instance field. The instance is referenced by vy.5920 0200 - iput v0,v2, Test2.i6:I // field@0002
Stores v0 into field@0002 (entry #2 in the field id table). The instance is referenced by v2.
5Aiput-wide vx,vy, field_idPuts the wide value located in vx and vx+1 registers into an instance field. The instance is referenced by vy.5A20 0000 - iput-wide v0,v2, Test2.d0:D // field@0000
Stores the wide value in v0, v1 registers into field@0000 (entry #0 in the field id table). The instance is referenced by v2.
5Biput-object vx,vy,field_idPuts the object reference in vx into an instance field. The instance is referenced by vy.5B20 0000 - iput-object v0, v2, LineReader.bis:Ljava/io/BufferedInputStream; // field@0000
Stores the object reference in v0 into field@0000 (entry #0 in the field table). The instance is referenced by v2.
5Ciput-boolean vx,vy, field_idPuts the boolean value located in vx into an instance field. The instance is referenced by vy.5C30 0000 - iput-boolean v0, v3, Test2.b0:Z // field@0000
Puts the boolean value in v0 into field@0000 (entry #0 in the field id table). The instance is referenced by v3.
5Diput-byte vx,vy,field_idPuts the byte value located in vx into an instance field. The instance is referenced by vy.5D20 0100 - iput-byte v0, v2, Test3.bi1:B // field@0001
Puts the boolean value in v0 into field@0001 (entry #1 in the field id table). The instance is referenced by v2.
5Eiput-char vx,vy,field_idPuts the char value located in vx into an instance field. The instance is referenced by vy.5E20 0300 - iput-char v0, v2, Test3.ci1:C // field@0003
Puts the char value in v0 into field@0003 (entry #3 in the field id table). The instance is referenced by v2.
5Fiput-short vx,vy,field_idPuts the short value located in vx into an instance field. The instance is referenced by vy.5F21 0800 - iput-short v1, v2, Test3.si1:S // field@0008
Puts the short value in v1 into field@0008 (entry #8 in the field id table). The instance is referenced by v2.
60sget vx,field_idReads the integer field identified by the field_id into vx.6000 0700 - sget v0, Test3.is1:I // field@0007
Reads field@0007 (entry #7 in the field id table) into v0.
61sget-wide vx, field_idReads the static field identified by the field_id into vx and vx+1 registers.6100 0500 - sget-wide v0, Test2.l1:J // field@0005
Reads field@0005 (entry #5 in the field id table) into v0 and v1 registers.
62sget-object vx,field_idReads the object reference field identified by the field_id into vx.6201 0C00 - sget-object v1, Test3.os1:Ljava/lang/Object; // field@000c
Reads field@000c (entry #CH in the field id table) into v1.
63sget-boolean vx,field_idReads the boolean static field identified by the field_id into vx.6300 0C00 - sget-boolean v0, Test2.sb:Z // field@000c
Reads boolean field@000c (entry #12 in the field id table) into v0.
64sget-byte vx,field_idReads the byte static field identified by the field_id into vx.6400 0200 - sget-byte v0, Test3.bs1:B // field@0002
Reads byte field@0002 (entry #2 in the field id table) into v0.
65sget-char vx,field_idReads the char static field identified by the field_id into vx.6500 0700 - sget-char v0, Test3.cs1:C // field@0007
Reads byte field@0007 (entry #7 in the field id table) into v0.
66sget-short vx,field_idReads the short static field identified by the field_id into vx.6600 0B00 - sget-short v0, Test3.ss1:S // field@000b
Reads short field@000b (entry #BH in the field id table) into v0.
67sput vx, field_idPuts vx into a static field.6700 0100 - sput v0, Test2.i5:I // field@0001
Stores v0 into field@0001 (entry #1 in the field id table).
68sput-wide vx, field_idPuts vx and vx+1 into a static field.6800 0500 - sput-wide v0, Test2.l1:J // field@0005
Puts the long value in v0 and v1 into the field@0005 static field (entry #5 in the field id table).
69sput-object vx,field_idPuts object reference in vx into a static field.6900 0c00 - sput-object v0, Test3.os1:Ljava/lang/Object; // field@000c
Puts the object reference value in v0 into the field@000c static field (entry #CH in the field id table).
6Asput-boolean vx,field_idPuts boolean value in vx into a static field.6A00 0300 - sput-boolean v0, Test3.bls1:Z // field@0003
Puts the byte value in v0 into the field@0003 static field (entry #3 in the field id table).
6Bsput-byte vx,field_idPuts byte value in vx into a static field.6B00 0200 - sput-byte v0, Test3.bs1:B // field@0002
Puts the byte value in v0 into the field@0002 static field (entry #2 in the field id table).
6Csput-char vx,field_idPuts char value in vx into a static field.6C01 0700 - sput-char v1, Test3.cs1:C // field@0007
Puts the char value in v1 into the field@0007 static field (entry #7 in the field id table).
6Dsput-short vx,field_idPuts short value in vx into a static field.6D00 0B00 - sput-short v0, Test3.ss1:S // field@000b
Puts the short value in v0 into the field@000b static field (entry #BH in the field id table).
6Einvoke-virtual { parameters }, methodtocallInvokes a virtual method with parameters.6E53 0600 0421 - invoke-virtual { v4, v0, v1, v2, v3}, Test2.method5:(IIII)V // method@0006
Invokes the 6th method in the method table with the following arguments: v4 is the "this" instance, v0, v1, v2, and v3 are the method parameters. The method has 5 arguments (4 MSB bits of the second byte)5.
6Finvoke-super {parameter},methodtocallInvokes the virtual method of the immediate parent class.6F10 A601 0100 invoke-super {v1},java.io.FilterOutputStream.close:()V // method@01a6
Invokes method@01a6 with one parameter, v1.
70invoke-direct { parameters }, methodtocallInvokes a method with parameters without the virtual method resolution.7010 0800 0100 - invoke-direct {v1}, java.lang.Object.<init>:()V // method@0008
Invokes the 8th method in the method table with just one parameter, v1 is the "this" instance5.
71invoke-static {parameters}, methodtocallInvokes a static method with parameters.7110 3400 0400 - invoke-static {v4}, java.lang.Integer.parseInt:( Ljava/lang/String;)I // method@0034
Invokes method@34 static method. The method is called with one parameter, v45.
72invoke-interface {parameters},methodtocallInvokes an interface method.7240 2102 3154 invoke-interface {v1, v3, v4, v5}, mwfw.IReceivingProtocolAdapter.receivePackage:(
ILjava/lang/String;Ljava/io/InputStream;)Z // method@0221
Invokes method@221 interface method using parameters in v1,v3,v4 and v55.
73unused_73

74invoke-virtual/range {vx..vy},methodtocallInvokes virtual method with a range of registers. The instruction specifies the first register and the number of registers to be passed to the method.7403 0600 1300 - invoke-virtual {v19..v21}, Test2.method5:(IIII)V // method@0006
Invokes the 6th method in the method table with the following arguments: v19 is the "this" instance, v20 and v21 are the method parameters. 
75invoke-super/rangeInvokes  the virtual method of the immediate parent class. The instruction specifies the first register and the number of registers to be passed to the method.7501 A601 0100 invoke-super {v1},java.io.FilterOutputStream.close:()V // method@01a6
Invokes method@01a6 with one parameter, v1.
76invoke-direct/range {vx..vy},methodtocallInvokes direct method with a range of registers. The instruction specifies the first register and the number of registers to be passed to the method.7603 3A00 1300 - invoke-direct/range {v19..21},java.lang.Object.<init>:()V // method@003a
Invokes method@3A with 1 parameters (second byte of the instruction=03). The parameter is stored in v19 (5th,6th bytes of the instruction).
77invoke-static/range {vx..vy},methodtocallInvokes static method with a range of registers. The instruction specifies the first register and the number of registers to be passed to the method.7703 3A00 1300 - invoke-static/range {v19..21},java.lang.Integer.parseInt:( Ljava/lang/String;)I // method@0034
Invokes method@3A with 1 parameters (second byte of the instruction=03). The parameter is stored in v19 (5th,6th bytes of the instruction).
78invoke-interface-rangeInvokes an interface method with a range of registers. The instruction specifies the first register and the number of registers to be passed to the method.7840 2102 0100 invoke-interface {v1..v4}, mwfw.IReceivingProtocolAdapter.receivePackage:(
ILjava/lang/String;Ljava/io/InputStream;)Z // method@0221
Invokes method@221 interface method using parameters in v1..v4.
79unused_79

7Aunused_7A

7Bneg-int vx,vyCalculates vx=-vy.7B01 - neg-int v1,v0
Calculates -v0 and stores the result in v1.
7Cnot-int vx,vy

7Dneg-long vx,vyCalculates vx,vx+1=-(vy,vy+1) 7D02 - neg-long v2,v0
Calculates -(v0,v1) and stores the result into (v2,v3)
7Enot-long vx,vy

7Fneg-float vx,vyCalculates vx=-vy7F01 - neg-float v1,v0
Calculates -v0 and stores the result into v1.
80neg-double vx,vyCalculates vx,vx+1=-(vy,vy+1)8002 - neg-double v2,v0
Calculates -(v0,v1) and stores the result into (v2,v3)
81int-to-long vx, vyConverts the integer in vy into a long in vx,vx+1.8106 - int-to-long v6, v0
Converts an integer in v0 into a long in v6,v7.
82int-to-float vx, vyConverts the integer in vx into a float in vx.8206 - int-to-float v6, v0
Converts the integer in v0 into a float in v6.
83int-to-double vx, vyConverts the integer in vy into the double in vx,vx+1.8306 - int-to-double v6, v0
Converts the integer in v0 into a double in v6,v7
84long-to-int vx,vyConverts the long value in vy,vy+1 into an integer in vx.8424 - long-to-int v4, v2
Converts the long value in v2,v3 into an integer value in v4.
85long-to-float vx, vyConverts the long value in vy,vy+1 into a float in vx.8510 - long-to-float v0, v1
Convcerts the long value in v1,v2 into a float value in v0.
86long-to-double vx, vyConverts the long value in vy,vy+1 into a double value in vx,vx+1.8610 - long-to-double v0, v1
Converts the long value in v1,v2 into a double value in v0,v1.
87float-to-int vx, vyConverts the float value in vy into an integer value in vx.8730 - float-to-int v0, v3
Converts the float value in v3 into an integer value in v0.
88float-to-long vx,vyConverts the float value in vy into a long value in vx.8830 - float-to-long v0, v3
Converts the float value in v3 into a long value in v0,v1.
89float-to-double vx, vyConverts the float value in vy into a double value in vx,vx+1.8930 - float-to-double v0, v3
Converts the float value in v3 into a double value in v0,v1.
8Adouble-to-int vx, vyConverts the double value in vy,vy+1 into an integer value in vx.8A40  - double-to-int v0, v4
Converts the double value in v4,v5 into an integer value in v0.
8Bdouble-to-long vx, vyConverts the double value in vy,vy+1 into a long value in vx,vx+1.8B40 - double-to-long v0, v4
Converts the double value in v4,v5 into a long value in v0,v1.
8Cdouble-to-float vx, vyConverts the double value in vy,vy+1 into a float value in vx.8C40 - double-to-float v0, v4
Converts the double value in v4,v5 into a float value in v0,v1.
8Dint-to-byte vx,vyConverts the int value in vy to a byte value and stores it in vx.8D00 - int-to-byte v0, v0
Converts the integer in v0 into a byte and puts the byte value into v0.
8Eint-to-char vx,vyConverts the int value in vy to a char value and stores it in vx.8E33  - int-to-char v3, v3
Converts the integer in v3 into a char and puts the char value into v3.
8Fint-to-short vx,vyConverts the int value in vy to a short value and stores it in vx.8F00 - int-to-short v0, v0
Converts the integer in v0 into a short and puts the short value into v3.
90add-int vx,vy,vzCalculates vy+vz and puts the result into vx.9000 0203 - add-int v0, v2, v3
Adds v3 to v2 and puts the result into v04.
91sub-int vx,vy,vzCalculates vy-vz and puts the result into vx.9100 0203 - sub-int v0, v2, v3
Subtracts v3 from v2 and puts the result into v0.
92mul-int vx, vy, vzMultiplies vz with wy and puts the result int vx.9200 0203 - mul-int v0,v2,v3
Multiplies v2 with w3 and puts the result into v0
93div-int vx,vy,vzDivides vy with vz and puts the result into vx.9303 0001 - div-int v3, v0, v1
Divides v0 with v1 and puts the result into v3.
94rem-int vx,vy,vzCalculates vy % vz and puts the result into vx.9400 0203 - rem-int v0, v2, v3
Calculates v3 % v2 and puts the result into v0.
95and-int vx, vy, vzCalculates vy AND vz and puts the result into vx.9503 0001 - and-int v3, v0, v1
Calculates v0 AND v1 and puts the result into v3.
96or-int vx, vy, vzCalculates vy OR vz and puts the result into vx.9603 0001 - or-int v3, v0, v1
Calculates v0 OR v1 and puts the result into v3.
97xor-int vx, vy, vzCalculates vy XOR vz and puts the result into vx.9703 0001 - xor-int v3, v0, v1
Calculates v0 XOR v1 and puts the result into v3.
98shl-int vx, vy, vzShift vy left by the positions specified by vz and store the result into vx.9802 0001 - shl-int v2, v0, v1
Shift v0 left by the positions specified by v1 and store the result in v2.
99shr-int vx, vy, vzShift vy right by the positions specified by vz and store the result into vx.9902 0001 - shr-int v2, v0, v1
Shift v0 right by the positions specified by v1 and store the result in v2.
9Aushr-int vx, vy, vzUnsigned shift right (>>>) vy by the positions specified by vz and store the result into vx.9A02 0001 - ushr-int v2, v0, v1
Unsigned shift v0 right by the positions specified by v1 and store the result in v2.
9Badd-long vx, vy, vzAdds vy to vz and puts the result into vx1.9B00 0305 - add-long v0, v3, v5
The long value in v3,v4 is added to the value in v5,v6 and the result is stored in v0,v1.
9Csub-long vx,vy,vzCalculates vy-vz and puts the result into vx1.9C00 0305 - sub-long v0, v3, v5
Subtracts the long value in v5,v6 from the long value in v3,v4 and puts the result into v0,v1.
9Dmul-long vx,vy,vzCalculates vy*vz and puts the result into vx1.9D00 0305 - mul-long v0, v3, v5
Multiplies the long value in v5,v6 with the long value in v3,v4 and puts the result into v0,v1.
9Ediv-long vx, vy, vzCalculates vy/vz and puts the result into vx1.9E06 0002 - div-long v6, v0, v2
Divides the long value in v0,v1 with the long value in v2,v3 and pust the result into v6,v7.
9Frem-long vx,vy,vzCalculates vy % vz and puts the result into vx1.9F06 0002 - rem-long v6, v0, v2
Calculates v0,v1 %  v2,v3 and puts the result into v6,v7.
A0and-long vx, vy, vzCalculates the vy AND vz and puts the result into vx1.A006 0002 - and-long v6, v0, v2
Calculates v0,v1 AND v2,v3 and puts the result into v6,v7.
A1or-long vx, vy, vzCalculates the vy OR vz and puts the result into vx1.A106 0002 - or-long v6, v0, v2
Calculates v0,v1 OR v2,v3 and puts the result into v6,v7.
A2xor-long vx, vy, vzCalculates the vy XOR vz and puts the result into vx1.A206 0002 - xor-long v6, v0, v2
Calculates v0,v1 XOR v2,v3 and puts the result into v6,v7.
A3shl-long vx, vy, vzShifts left vy by vz positions and stores the result in vx1.A302 0004 - shl-long v2, v0, v4
Shift v0,v1 by postions specified by v4 and puts the result into v2,v3.
A4shr-long vx,vy,vzShifts right vy by vz positions and stores the result in vx1.A402 0004 - shr-long v2, v0, v4
Shift v0,v1 by postions specified by v4 and puts the result into v2,v3.
A5ushr-long vx, vy, vzUnsigned shifts right vy by vz positions and stores the result in vx1.A502 0004 - ushr-long v2, v0, v4
Unsigned shift v0,v1 by postions specified by v4 and puts the result into v2,v3.
A6add-float vx,vy,vzAdds vy to vz and puts the result into vx.A600 0203 - add-float v0, v2, v3
Adds the floating point numbers in v2 and v3 and puts the result into v0.
A7sub-float vx,vy,vzCalculates vy-vz and puts the result into vx.A700 0203 - sub-float v0, v2, v3
Calculates v2-v3 and puts the result into v0.
A8mul-float vx, vy, vzMultiplies vy with vz and puts the result into vx.A803 0001 - mul-float v3, v0, v1
Multiplies v0 with v1 and puts the result into v3.
A9div-float vx, vy, vzCalculates vy/vz and puts the result into vx.A903 0001 - div-float v3, v0, v1
Divides v0 with v1 and puts the result into v3.
AArem-float vx,vy,vzCalculates vy % vz and puts the result into vx.AA03 0001 - rem-float v3, v0, v1
Calculates v0 %  v1 and puts the result into v3.
ABadd-double vx,vy,vzAdds vy to vz and puts the result into vx1AB00 0305 - add-double v0, v3, v5
Adds the double value in v5,v6 registers to the double value in v3,v4 registers and places the result  in v0,v1 registers.
ACsub-double vx,vy,vzCalculates vy-vz and puts the result into vx1.AC00 0305 - sub-double v0, v3, v5
Subtracts the value in v5,v6 from the value in v3,v4 and puts the result into v0,v1.
ADmul-double vx, vy, vzMultiplies vy with vz and puts the result into vx1.AD06 0002 - mul-double v6, v0, v2
Multiplies the double value in v0,v1 with the double value in v2,v3 and puts the result into v6,v7.
AEdiv-double vx, vy, vzCalculates vy/vz and puts the result into vx1.AE06 0002 - div-double v6, v0, v2
Divides the double value in v0,v1 with the double value in v2,v3 and puts the result into v6,v7.
AFrem-double vx,vy,vzCalculates vy % vz and puts the result into vx1.AF06 0002 - rem-double v6, v0, v2
Calculates v0,v1 % v2,v3 and puts the result into v6,v7.
B0add-int/2addr vx,vyAdds vy to vx.B010 - add-int/2addr v0,v1
Adds v1 to v0.
B1sub-int/2addr vx,vyCalculates vx-vy and puts the result into vx.B140 - sub-int/2addr v0, v4
Subtracts v4 from v0 and puts the result into v0.
B2mul-int/2addr vx,vyMultiplies vx with vy.B210 - mul-int/2addr v0, v1
Multiples v0 with v1 and puts the result into v0.
B3div-int/2addr vx,vyDivides vx with vy and puts the result into vx.B310 - div-int/2addr v0, v1
Divides v0 with v1 and puts the result into v0.
B4rem-int/2addr vx,vyCalculates vx % vy and puts the result into vxB410 - rem-int/2addr v0, v1
 Calculates v0 % v1 and puts the result into v0.
B5and-int/2addr vx, vyCalculates vx AND vy and puts the result into vx.B510 - and-int/2addr v0, v1
Calculates v0 AND v1 and puts the result into v0.
B6or-int/2addr vx, vyCalculates vx OR vy and puts the result into vx.B610 - or-int/2addr v0, v1
Calculates v0 OR v1 and puts the result into v0.
B7xor-int/2addr vx, vyCalculates vx XOR vy and puts the result into vx.B710  - xor-int/2addr v0, v1
Calculates v0 XOR v1 and puts the result into v0.
B8shl-int/2addr vx, vyShifts vx left by vy positions.B810 - shl-int/2addr v0, v1
Shift v0 left by v1 positions.
B9shr-int/2addr vx, vyShifts vx right by vy positions.B910 - shr-int/2addr v0, v1
Shift v0 right by v1 positions.
BAushr-int/2addr vx, vyUnsigned shift right (>>>) vx by the positions specified by vy.BA10 - ushr-int/2addr v0, v1
Unsigned shift v0 by the positions specified by v1.
BBadd-long/2addr vx,vyAdds vy to vx1.BB20 - add-long/2addr v0, v2
Adds the long value in v2,v3 registers to the long value in v0,v1 registers.
BCsub-long/2addr vx,vyCalculates vx-vy and puts the result into vx1.BC70 - sub-long/2addr v0, v7
Subtracts the long value in v7,v8 from the long value in v0,v1 and puts the result into v0,v1.
BDmul-long/2addr vx,vyCalculates vx*vy and puts the result into vx1.BD70 - mul-long/2addr v0, v7
Multiplies the long value in v7,v8 with the long value in v0,v1 and puts the result into v0,v1.
BEdiv-long/2addr vx, vyCalculates vx/vy and puts the result into vx1.BE20 - div-long/2addr v0, v2
Divides the long value in v0,v1 with the long value in v2,v3 and puts the result into v0,v1
BFrem-long/2addr vx,vyCalculates vx % vy and puts the result into vx1.BF20 - rem-long/2addr v0, v2
Calculates v0,v1 % v2,v3 and puts the result into v0,v1
C0and-long/2addr vx, vyCalculates vx AND vy and puts the result into vx1.C020 - and-long/2addr v0, v2
Calculates v0,v1 OR v2,v3 and puts the result into v0,v1.
C1or-long/2addr vx, vyCalculates vx OR vy and puts the result into vx1.C120  - or-long/2addr v0, v2
Calculates v0,v1 OR v2,v3 and puts the result into v0,v1.
C2xor-long/2addr vx, vyCalculates vx XOR vy and puts the result into vx1.C220 - xor-long/2addr v0, v2
Calculates v0,v1 XOR v2,v3 and puts the result into v0,v1.
C3shl-long/2addr vx, vyShifts left the value in vx,vx+1 by the positions specified by vy and stores the result in vx,vx+1.C320 - shl-long/2addr v0, v2
Shifts left v0,v1 by the positions specified by v2.
C4shr-long/2addr vx, vyShifts right the value in vx,vx+1 by the positions specified by vy and stores the result in vx,vx+1.C420 - shr-long/2addr v0, v2
Shifts right v0,v1 by the positions specified by v2.
C5ushr-long/2addr vx, vyUnsigned shifts right the value in vx,vx+1 by the positions specified by vy and stores the result in vx,vx+1.C520 - ushr-long/2addr v0, v2
Unsigned shifts right v0,v1 by the positions specified by v2.
C6add-float/2addr vx,vyAdds vy to vx. C640 - add-float/2addr v0,v4
Adds v4 to v0.
C7sub-float/2addr vx,vyCalculates vx-vy and stores the result in vx.C740 - sub-float/2addr v0,v4
Adds v4 to v0.
C8mul-float/2addr vx, vyMultiplies vx with vy.C810 - mul-float/2addr v0, v1
Multiplies v0 with v1.
C9div-float/2addr vx, vyCalculates vx/vy and puts the result into vx.C910 - div-float/2addr v0, v1
Divides v0 with v1 and puts the result into v0.
CArem-float/2addr vx,vyCalculates vx/vy and puts the result into vx.CA10 - rem-float/2addr v0, v1
 Calculates v0 % v1 and puts the result into v0.
CBadd-double/2addr vx, vyAdds vy to vx1.CB70 - add-double/2addr v0, v7
Adds v7 to v0.
CCsub-double/2addr vx, vyCalculates vx-vy and puts the result into vx1.CC70 - sub-double/2addr v0, v7
Subtracts the value in v7,v8 from the value in v0,v1 and puts the result into v0,v1.
CDmul-double/2addr vx, vyMultiplies vx with vy1.CD20 - mul-double/2addr v0, v2
Multiplies the double value in v0,v1 with the double value in v2,v3 and puts the result into v0,v1.
CEdiv-double/2addr vx, vyCalculates vx/vy and puts the result into vx1.CE20 - div-double/2addr v0, v2
Divides the double value in v0,v1 with the double value in v2,v3 and puts the value into v0,v1.
CFrem-double/2addr vx,vyCalculates vx % vy and puts the result into vx1.CF20 - rem-double/2addr v0, v2
 Calculates  v0,v1 %  v2,v3 and puts the value into v0,v1.
D0add-int/lit16 vx,vy,lit16Adds vy to lit16 and stores the result into vx.D001 D204 - add-int/lit16 v1, v0, #int 1234 // #04d2
Adds v0 to literal 1234 and stores the result into v1.
D1sub-int/lit16 vx,vy,lit16Calculates vy - lit16 and stores the result into vx.D101 D204 - sub-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 - literal 1234 and stores the result into v1.
D2mul-int/lit16 vx,vy,lit16Calculates vy * lit16 and stores the result into vx.D201 D204 - mul-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 * literal 1234 and stores the result into v1.
D3div-int/lit16 vx,vy,lit16Calculates vy / lit16 and stores the result into vx.D301 D204 - div-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 / literal 1234 and stores the result into v1.
D4rem-int/lit16 vx,vy,lit16Calculates vy % lit16 and stores the result into vx.D401 D204 - rem-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 % literal 1234 and stores the result into v1.
D5and-int/lit16 vx,vy,lit16Calculates vy AND lit16 and stores the result into vx.D501 D204 - and-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 AND literal 1234 and stores the result into v1.
D6or-int/lit16 vx,vy,lit16Calculates vy OR lit16 and stores the result into vx.D601 D204 - or-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 OR literal 1234 and stores the result into v1.
D7xor-int/lit16 vx,vy,lit16Calculates vy XOR lit16 and stores the result into vx.D701 D204 - xor-int/lit16 v1, v0, #int 1234 // #04d2
Calculates v0 XOR literal 1234 and stores the result into v1.
D8add-int/lit8 vx,vy,lit8Adds vy to lit8 and stores the result into vx.D800 0201 - add-int/lit8 v0,v2, #int1
Adds literal 1 to v2 and stores the result into v0.
D9sub-int/lit8 vx,vy,lit8Calculates vy-lit8 and stores the result into vx.D900 0201 - sub-int/lit8 v0,v2, #int1
Calculates v2-1 and stores the result into v0.
DAmul-int/lit8 vx,vy,lit8Multiplies vy with lit8 8-bit literal constant and puts the result into vx.DA00 0002 - mul-int/lit8 v0,v0, #int2
Multiplies v0 with literal 2 and puts the result into v0.
DBdiv-int/lit8 vx,vy,lit8Calculates vy/lit8 and stores the result into vx.DB00 0203 - mul-int/lit8 v0,v2, #int3
Calculates v2/3 and stores the result into v0.
DCrem-int/lit8 vx,vy,lit8Calculates vy % lit8 and stores the result into vx.DC00 0203 - rem-int/lit8 v0,v2, #int3
Calculates v2 % 3 and stores the result into v0.
DDand-int/lit8 vx,vy,lit8Calculates vy AND lit8 and stores the result into vx.DD00 0203 - and-int/lit8 v0,v2, #int3
Calculates v2 AND 3 and stores the result into v0.
DEor-int/lit8 vx, vy, lit8Calculates vy OR lit8 and puts the result into vx.DE00 0203 - or-int/lit8 v0, v2, #int 3
Calculates v2 OR literal 3 and puts the result into v0.
DFxor-int/lit8 vx, vy, lit8Calculates vy XOR lit8 and puts the result into vx.DF00 0203     |  0008: xor-int/lit8 v0, v2, #int 3
Calculates v2 XOR literal 3 and puts the result into v0.
E0shl-int/lit8 vx, vy, lit8Shift v0 left by the bit positions specified by the literal constant and put the result into vx.E001 0001 - shl-int/lit8 v1, v0, #int 1
Shift v0 left by 1 position and put the result into v1.
E1shr-int/lit8 vx, vy, lit8Shift v0 right by the bit positions specified by the literal constant and put the result into vx.E101 0001 - shr-int/lit8 v1, v0, #int 1
Shift v0 right by 1 position and put the result into v1.
E2ushr-int/lit8 vx, vy, lit8Unsigned right shift of v0 (>>>) by the bit positions specified by the literal constant and put the result into vx.E201 0001 - ushr-int/lit8 v1, v0, #int 1
Unsigned shift v0 right by 1 position and put the result into v1.
E3unused_E3

E4unused_E4

E5unused_E5

E6unused_E6

E7unused_E7

E8unused_E8

E9unused_E9

EAunused_EA

EBunused_EB

ECunused_EC

EDunused_ED

EEexecute-inline {parameters},inline IDExecutes the inline method identified by inline ID6.EE20 0300 0100 - execute-inline {v1, v0}, inline #0003
Executes inline method #3 using v1 as "this" and passing one parameter in v0.
EFunused_EF

F0invoke-direct-emptyStands as a placeholder for pruned empty methods like Object.<init>. This acts as nop during normal execution6.F010 F608 0000 - invoke-direct-empty {v0}, Ljava/lang/Object;.<init>:()V // method@08f6
Replacement for the empty method java/lang/Object;<init>.
F1unused_F1

F2iget-quick vx,vy,offsetGets the value stored at offset in vy instance's data area to vx6.F221 1000 - iget-quick v1, v2, [obj+0010]
Gets the value at offset 0CH of the instance pointed by v2 and stores the object reference in v1.
F3iget-wide-quick vx,vy,offsetGets the object reference value stored at offset in vy instance's data area to vx,vx+16.F364 3001 - iget-wide-quick v4, v6, [obj+0130]
Gets the value at offset 130H of the instance pointed by v6 and stores the object reference in v4,v5.
F4iget-object-quick vx,vy,offsetGets the object reference value stored at offset in vy instance's data area to vx6.F431 0C00 - iget-object-quick v1, v3, [obj+000c]
Gets the object reference value at offset 0CH of the instance pointed by v3 and stores the object reference in v1.
F5iput-quick vx,vy,offsetPuts the value stored in vx to offset in vy instance's data area6.F521 1000  - iput-quick v1, v2, [obj+0010]
Puts the object reference value in v1 to offset 10H of the instance pointed by v2.
F6iput-wide-quick vx,vy,offsetPuts the value stored in vx,vx+1 to offset in vy instance's data area6.F652 7001 - iput-wide-quick v2, v5, [obj+0170]
Puts the value in v2,v3 to offset 170H of the instance pointed by v5.
F7iput-object-quick vx,vy,offsetPuts the object reference value stored in vx to offset in vy instance's data area to vx6.F701 4C00 - iput-object-quick v1, v0, [obj+004c]
Puts the object reference value in v1 to offset 0CH of the instance pointed by v3.
F8invoke-virtual-quick {parameters},vtable offsetInvokes a virtual method using the vtable of the target object6.F820 B800 CF00 - invoke-virtual-quick {v15, v12}, vtable #00b8
Invokes a virtual method. The target object instance is pointed by v15 and vtable entry #B8 points to the method to be called. v12 is a parameter to the method call.
F9invoke-virtual-quick/range {parameter range},vtable offsetInvokes a virtual method using the vtable of the target object6F906 1800 0000 - invoke-virtual-quick/range {v0..v5},vtable #0018
Invokes a method using the vtable of the instance pointed by v0. v1..v5 registers are parameters to the method call.
FAinvoke-super-quick {parameters},vtable offsetInvokes a virtual method in the target object's immediate parent class using the vtable of that parent class6.FA40 8100 3254  - invoke-super-quick {v2, v3, v4, v5}, vtable #0081
Invokes a method using the vtable of the immediate parent class of instance pointed by v2. v3, v4 and v5 registers are parameters to the method call.
FBinvoke-super-quick/range {register range},vtable offsetInvokes a virtual method in the target object's immediate parent class using the vtable of that parent class6.F906 1B00 0000 - invoke-super-quick/range {v0..v5}, vtable #001b
Invokes a method using the vtable of the immediate parent class of instance pointed by v0. v1..v5 registers are parameters to the method call.
FCunused_FC

FDunused_FD

FEunused_FE

FFunused_FF



  1. Note that double and long values occupy two registers (e.g. the value addressed by vy is located in vy and vy+1 registers)
  2. The offset can be positive or negative and it is calculated from the offset of the starting byte of the instruction. The offset is always interpreted in words (2 bytes per 1 offset value increment/decrement). Negative offset is stored in two's complement format. The current position is the offset of the starting byte of the instruction.
  3. Compare operations returrn positive value if the first operand is greater than the second operand, 0 if they are equal and negative value if the first operand is smaller than the second operand.
  4. Not seen in the wild, interpolated from Dalvik bytecode list.
  5. The invocation parameter list encoding is somewhat weird. Starting if parameter number > 4 and parameter number % 4 == 1, the 5th (9th, etc.) parameter is encoded on the 4 lowest bit of the byte immediately following the instruction. Curiously, this encoding is not used in case of 1 parameter, in this case an entire 16 bit word is added after the method index of which only 4 bit is used to encode the single parameter while the lowest 4 bit of the byte following the instruction byte is left unused.
  6. This is an unsafe instruction and occurs only in ODEX files.