4 Specialized Decodes
When performance is of highest priority and you are interested in a limited part of the ASN.1 encoded message before deciding what to do with the rest of it, an option is to decode only this small part. The situation can be a server that has to decide the addressee of a message. The addressee can be interested in the entire message, but the server can be a bottleneck that you want to spare any unnecessary load.
Instead of making two complete decodes (the normal case of decode), one in the server and one in the addressee, it is only necessary to make one specialized decode(in the server) and another complete decode(in the addressee). This section describes the following two specialized decodes, which support to solve this and similar problems:
- Exclusive decode
- Selected decode
This functionality is only provided when using BER
(option ber
).
4.1 Exclusive Decode
The basic idea with exclusive decode is to specify which parts of the message you want to exclude from being decoded. These parts remain encoded and are returned in the value structure as binaries. They can be decoded in turn by passing them to a certain decode_part/2
function. The performance gain is high for large messages. You can do an exclusive decode and later one or more decodes of the parts, or a second complete decode instead of two or more complete decodes.
Procedure
To perform an exclusive decode:
- Step 1: Decide the name of the function for the exclusive decode.
-
Step 2: Include the following instructions in a configuration file:
- The name of the exclusive decode function
- The name of the ASN.1 specification
- A notation that tells which parts of the message structure to be excluded from decode
- Step 3 Compile with the additional option
asn1config
. The compiler searches for a configuration file with the same name as the ASN.1 specification but with extension.asn1config
. This configuration file is not the same as used for compilation of a set of files. See SectionWriting an Exclusive Decode Instruction.
User Interface
The runtime user interface for exclusive decode consists of the following two functions:
- A function for an exclusive decode, whose name the user decides in the configuration file
- The compiler generates a
decode_part/2
function when exclusive decode is chosen. This function decodes the parts that were left undecoded during the exclusive decode.
Both functions are described in the following.
If the exclusive decode function has, for example, the name decode_exclusive
and an ASN.1 encoded message Bin
is to be exclusive decoded, the call is as follows:
{ok,Excl_Message} = 'MyModule':decode_exclusive(Bin)
The result Excl_Message
has the same structure as a complete decode would have, except for the parts of the top type that were not decoded. The undecoded parts are on their places in the structure on format {Type_Key,Undecoded_Value}
.
Each undecoded part that is to be decoded must be fed into function decode_part/2
as follows:
{ok,Part_Message} = 'MyModule':decode_part(Type_Key,Undecoded_Value)
Writing an Exclusive Decode Instruction
This instruction is written in the configuration file in the following format:
Exclusive_Decode_Instruction = {exclusive_decode,{Module_Name,Decode_Instructions}}. Module_Name = atom() Decode_Instructions = [Decode_Instruction]+ Decode_Instruction = {Exclusive_Decode_Function_Name,Type_List} Exclusive_Decode_Function_Name = atom() Type_List = [Top_Type,Element_List] Element_List = [Element]+ Element = {Name,parts} | {Name,undecoded} | {Name,Element_List} Top_Type = atom() Name = atom()
The instruction must be a valid Erlang term ended by a dot.
In Type_List
the "path" from the top type to each undecoded subcomponents is described. The top type of the path is an atom, the name of it. The action on each component/type that follows is described by one of {Name,parts}, {Name,undecoded}, {Name,Element_List}
.
The use and effect of the actions are as follows:
-
{Name,undecoded}
- Tells that the element is left undecoded during the exclusive decode. The type ofName
can be any ASN.1 type. The value of elementName
is returned as a tuple (as mentioned in the previous section) in the value structure of the top type. -
{Name,parts}
- The type ofName
can be one ofSEQUENCE OF
orSET OF
. The action implies that the different components ofName
are left undecoded. The value ofName
is returned as a tuple (as mentioned in the previous section) where the second element is a list of binaries. This is because the representation of aSEQUENCE OF
or aSET OF
in Erlang is a list of its internal type. Any of the elements in this list or the entire list can be decoded by functiondecode_part
. -
{Name,Element_List}
- This action is used when one or more of the subtypes ofName
is exclusive decoded.
Name
in these actions can be a component name of a SEQUENCE OF
or a SET OF
, or a name of an alternative in a CHOICE
.
Example
In this examples, the definitions from the following ASN.1 specification are used:
GUI DEFINITIONS AUTOMATIC TAGS ::= BEGIN Action ::= SEQUENCE { number INTEGER DEFAULT 15, handle [0] Handle DEFAULT {number 12, on TRUE} } Key ::= [11] EXPLICIT Button Handle ::= [12] Key Button ::= SEQUENCE { number INTEGER, on BOOLEAN } Window ::= CHOICE { vsn INTEGER, status E } Status ::= SEQUENCE { state INTEGER, buttonList SEQUENCE OF Button, enabled BOOLEAN OPTIONAL, actions CHOICE { possibleActions SEQUENCE OF Action, noOfActions INTEGER } } END
If Button
is a top type and it is needed to exclude component number
from decode, Type_List
in the instruction in the configuration file is ['Button',[{number,undecoded}]]
. If you call the decode function decode_Button_exclusive
, Decode_Instruction
is {decode_Button_exclusive,['Button',[{number,undecoded}]]}
.
Another top type is Window
whose subcomponent actions in type Status
and the parts of component buttonList
are to be left undecoded. For this type, the function is named decode__Window_exclusive
. The complete Exclusive_Decode_Instruction
configuration is as follows:
{exclusive_decode,{'GUI', [{decode_Window_exclusive,['Window',[{status,[{buttonList,parts},{actions,undecoded}]}]]}, {decode_Button_exclusive,['Button',[{number,undecoded}]]}]}}.
The following figure shows the bytes of a Window:status
message. The components buttonList
and actions
are excluded from decode. Only state
and enabled
are decoded when decode__Window_exclusive
is called.
Compiling GUI.asn
including the configuration file is done as follows:
unix> erlc -bber +asn1config GUI.asn erlang> asn1ct:compile('GUI', [ber,asn1config]).
The module can be used as follows:
1> Button_Msg = {'Button',123,true}. {'Button',123,true} 2> {ok,Button_Bytes} = 'GUI':encode('Button',Button_Msg). {ok,[<<48>>, [6], [<<128>>, [1], 123], [<<129>>, [1], 255]]} 3> {ok,Exclusive_Msg_Button} = 'GUI':decode_Button_exclusive(list_to_binary(Button_Bytes)). {ok,{'Button',{'Button_number',<<28,1,123>>}, true}} 4> 'GUI':decode_part('Button_number',<<128,1,123>>). {ok,123} 5> Window_Msg = {'Window',{status,{'Status',35, [{'Button',3,true}, {'Button',4,false}, {'Button',5,true}, {'Button',6,true}, {'Button',7,false}, {'Button',8,true}, {'Button',9,true}, {'Button',10,false}, {'Button',11,true}, {'Button',12,true}, {'Button',13,false}, {'Button',14,true}], false, {possibleActions,[{'Action',16,{'Button',17,true}}]}}}}. {'Window',{status,{'Status',35, [{'Button',3,true}, {'Button',4,false}, {'Button',5,true}, {'Button',6,true}, {'Button',7,false}, {'Button',8,true}, {'Button',9,true}, {'Button',10,false}, {'Button',11,true}, {'Button',12,true}, {'Button',13,false}, {'Button',14,true}], false, {possibleActions,[{'Action',16,{'Button',17,true}}]}}}} 6> {ok,Window_Bytes}='GUI':encode('Window',Window_Msg). {ok,[<<161>>, [127], [<<128>>, ... 8> {ok,{status,{'Status',Int,{Type_Key_SeqOf,Val_SEQOF}, BoolOpt,{Type_Key_Choice,Val_Choice}}}}= 'GUI':decode_Window_status_exclusive(list_to_binary(Window_Bytes)). {ok,{status,{'Status',35, {'Status_buttonList',[<<48,6,128,1,3,129,1,255>>, <<48,6,128,1,4,129,1,0>>, <<48,6,128,1,5,129,1,255>>, <<48,6,128,1,6,129,1,255>>, <<48,6,128,1,7,129,1,0>>, <<48,6,128,1,8,129,1,255>>, <<48,6,128,1,9,129,1,255>>, <<48,6,128,1,10,129,1,0>>, <<48,6,128,1,11,129,1,255>>, <<48,6,128,1,12,129,1,255>>, <<48,6,128,1,13,129,1,0>>, <<48,6,128,1,14,129,1,255>>]}, false, {'Status_actions', <<163,21,160,19,48,17,2,1,16,160,12,172,10,171,8,48,6,128,1,...>>}}}} 10> 'GUI':decode_part(Type_Key_SeqOf,Val_SEQOF). {ok,[{'Button',3,true}, {'Button',4,false}, {'Button',5,true}, {'Button',6,true}, {'Button',7,false}, {'Button',8,true}, {'Button',9,true}, {'Button',10,false}, {'Button',11,true}, {'Button',12,true}, {'Button',13,false}, {'Button',14,true}]} 11> 'GUI':decode_part(Type_Key_SeqOf,hd(Val_SEQOF)). {ok,{'Button',3,true}} 12> 'GUI':decode_part(Type_Key_Choice,Val_Choice). {ok,{possibleActions,[{'Action',16,{'Button',17,true}}]}}
4.2 Selective Decode
This specialized decode decodes a subtype of a constructed value and is the fastest method to extract a subvalue. This decode is typically used when you want to inspect, for example, a version number, to be able to decide what to do with the entire value. The result is returned as {ok,Value}
or {error,Reason}
.
Procedure
To perform a selective decode:
-
Step 1: Include the following instructions in the configuration file:
- The name of the user function
- The name of the ASN.1 specification
- A notation that tells which part of the type to be decoded
- Step 2: Compile with the additional option
asn1config
. The compiler searches for a configuration file with the same name as the ASN.1 specification, but with extension.asn1config
. In the same file you can also provide configuration specifications for exclusive decode. The generated Erlang module has the usual functionality for encode/decode preserved and the specialized decode functionality added.
User Interface
The only new user interface function is the one provided by the user in the configuration file. The function is started by the ModuleName:FunctionName
notation.
For example, if the configuration file includes the specification {selective_decode,{'ModuleName',[{selected_decode_Window,TypeList}]}}
do the selective decode by {ok,Result}='ModuleName':selected_decode_Window(EncodedBinary).
Writing a Selective Decode Instruction
One or more selective decode functions can be described in a configuration file. Use the following notation:
Selective_Decode_Instruction = {selective_decode,{Module_Name,Decode_Instructions}}. Module_Name = atom() Decode_Instructions = [Decode_Instruction]+ Decode_Instruction = {Selective_Decode_Function_Name,Type_List} Selective_Decode_Function_Name = atom() Type_List = [Top_Type|Element_List] Element_List = Name|List_Selector Name = atom() List_Selector = [integer()]
The instruction must be a valid Erlang term ended by a dot.
-
Module_Name
is the same as the name of the ASN.1 specification, but without the extension. -
Decode_Instruction
is a tuple with your chosen function name and the components from the top type that leads to the single type you want to decode. Ensure to choose a name of your function that is not the same as any of the generated functions. - The first element of
Type_List
is the top type of the encoded message. InElement_List
, it is followed by each of the component names that leads to selected type. - Each name in
Element_List
must be a constructed type except the last name, which can be any type. -
List_Selector
makes it possible to choose one of the encoded components in a aSEQUENCE OF
or aSET OF
. It is also possible to go further in that component and pick a subtype of that to decode. So, in theType_List
:['Window',status,buttonList,[1],number]
, componentbuttonList
must be of typeSEQUENCE OF
orSET OF
.
In the example, component number
of the first of the encoded elements in the SEQUENCE OF
buttonList
is selected. This applies on the ASN.1 specification in Section Writing an Exclusive Decode Instruction
.
Another Example
In this example, the same ASN.1 specification as in Section Writing an Exclusive Decode Instruction
is used. The following is a valid selective decode instruction:
{selective_decode, {'GUI', [{selected_decode_Window1, ['Window',status,buttonList, [1], number]}, {selected_decode_Action, ['Action',handle,number]}, {selected_decode_Window2, ['Window', status, actions, possibleActions, [1], handle,number]}]}}.
The first instruction, {selected_decode_Window1,['Window',status,buttonList,[1],number]}
is described in the previous section.
The second instruction, {selected_decode_Action,['Action',handle,number]}
, takes component number
in the handle
component of type Action
. If the value is ValAction = {'Action',17,{'Button',4711,false}}
, the internal value 4711 is to be picked by selected_decode_Action
. In an Erlang terminal it looks as follows:
ValAction = {'Action',17,{'Button',4711,false}}. {'Action',17,{'Button',4711,false}} 7> {ok,Bytes}='GUI':encode('Action',ValAction). ... 8> BinBytes = list_to_binary(Bytes). <<48,18,2,1,17,160,13,172,11,171,9,48,7,128,2,18,103,129,1,0>> 9> 'GUI':selected_decode_Action(BinBytes). {ok,4711} 10>
The third instruction, ['Window',status,actions,possibleActions,[1],handle,number]
, works as follows:
- Step 1: Starts with type
Window
. - Step 2: Takes component
status
ofWindow
that is of typeStatus
. - Step 3: Takes actions of type
Status
. - Step 4: Takes
possibleActions
of the internally definedCHOICE
type. - Step 5: Goes into the first component of
SEQUENCE OF
by[1]
. That component is of typeAction
. - Step 6: Takes component
handle
. - Step 7: Takes component
number
of typeButton
.
The following figure shows which components are in TypeList
['Window',status,actions,possibleActions,[1],handle,number]
:
In the following figure, only the marked element is decoded by selected_decode_Window2
:
With the following example, you can examine that both selected_decode_Window2
and selected_decode_Window1
decodes the intended subvalue of value Val
:
1> Val = {'Window',{status,{'Status',12, [{'Button',13,true}, {'Button',14,false}, {'Button',15,true}, {'Button',16,false}], true, {possibleActions,[{'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}]}}}} 2> {ok,Bytes}='GUI':encode('Window',Val). ... 3> Bin = list_to_binary(Bytes). <<161,101,128,1,12,161,32,48,6,128,1,13,129,1,255,48,6,128,1,14,129,1,0,48,6,128,1,15,129,...>> 4> 'GUI':selected_decode_Window1(Bin). {ok,13} 5> 'GUI':selected_decode_Window2(Bin). {ok,18}
Notice that the value fed into the selective decode functions must be a binary.
4.3 Performance
To give an indication on the possible performance gain using the specialized decodes, some measures have been performed. The relative figures in the outcome between selective, exclusive, and complete decode (the normal case) depend on the structure of the type, the size of the message, and on what level the selective and exclusive decodes are specified.
ASN.1 Specifications, Messages, and Configuration
The specifications GUI
and MEDIA-GATEWAY-CONTROL
were used in the test.
For the GUI
specification the configuration was as follows:
{selective_decode, {'GUI', [{selected_decode_Window1, ['Window', status,buttonList, [1], number]}, {selected_decode_Window2, ['Window', status, actions, possibleActions, [1], handle,number]}]}}. {exclusive_decode, {'GUI', [{decode_Window_status_exclusive, ['Window', [{status, [{buttonList,parts}, {actions,undecoded}]}]]}]}}.
The MEDIA-GATEWAY-CONTROL
configuration was as follows:
{exclusive_decode, {'MEDIA-GATEWAY-CONTROL', [{decode_MegacoMessage_exclusive, ['MegacoMessage', [{authHeader,undecoded}, {mess, [{mId,undecoded}, {messageBody,undecoded}]}]]}]}}. {selective_decode, {'MEDIA-GATEWAY-CONTROL', [{decode_MegacoMessage_selective, ['MegacoMessage',mess,version]}]}}.
The corresponding values were as follows:
{'Window',{status,{'Status',12, [{'Button',13,true}, {'Button',14,false}, {'Button',15,true}, {'Button',16,false}, {'Button',13,true}, {'Button',14,false}, {'Button',15,true}, {'Button',16,false}, {'Button',13,true}, {'Button',14,false}, {'Button',15,true}, {'Button',16,false}], true, {possibleActions, [{'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}, {'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}, {'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}, {'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}, {'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}, {'Action',17,{'Button',18,false}}, {'Action',19,{'Button',20,true}}, {'Action',21,{'Button',22,false}}]}}}} {'MegacoMessage',asn1_NOVALUE, {'Message',1, {ip4Address, {'IP4Address',[125,125,125,111],55555}}, {transactions, [{transactionReply, {'TransactionReply',50007,asn1_NOVALUE, {actionReplies, [{'ActionReply',0,asn1_NOVALUE,asn1_NOVALUE, [{auditValueReply,{auditResult,{'AuditResult', {'TerminationID',[],[255,255,255]}, [{mediaDescriptor, {'MediaDescriptor',asn1_NOVALUE, {multiStream, [{'StreamDescriptor',1, {'StreamParms', {'LocalControlDescriptor', sendRecv, asn1_NOVALUE, asn1_NOVALUE, [{'PropertyParm', [0,11,0,7], [[52,48]], asn1_NOVALUE}]}, {'LocalRemoteDescriptor', [[{'PropertyParm', [0,0,176,1], [[48]], asn1_NOVALUE}, {'PropertyParm', [0,0,176,8], [[73,78,32,73,80,52,32,49,50,53,46,49, 50,53,46,49,50,53,46,49,49,49]], asn1_NOVALUE}, {'PropertyParm', [0,0,176,15], [[97,117,100,105,111,32,49,49,49,49,32, 82,84,80,47,65,86,80,32,32,52]], asn1_NOVALUE}, {'PropertyParm', [0,0,176,12], [[112,116,105,109,101,58,51,48]], asn1_NOVALUE}]]}, {'LocalRemoteDescriptor', [[{'PropertyParm', [0,0,176,1], [[48]], asn1_NOVALUE}, {'PropertyParm', [0,0,176,8], [[73,78,32,73,80,52,32,49,50,52,46,49,50, 52,46,49,50,52,46,50,50,50]], asn1_NOVALUE}, {'PropertyParm', [0,0,176,15], [[97,117,100,105,111,32,50,50,50,50,32,82, 84,80,47,65,86,80,32,32,52]], asn1_NOVALUE}, {'PropertyParm', [0,0,176,12], [[112,116,105,109,101,58,51,48]], asn1_NOVALUE}]]}}}]}}}, {packagesDescriptor, [{'PackagesItem',[0,11],1}, {'PackagesItem',[0,11],1}]}, {statisticsDescriptor, [{'StatisticsParameter',[0,12,0,4],[[49,50,48,48]]}, {'StatisticsParameter',[0,11,0,2],[[54,50,51,48,48]]}, {'StatisticsParameter',[0,12,0,5],[[55,48,48]]}, {'StatisticsParameter',[0,11,0,3],[[52,53,49,48,48]]}, {'StatisticsParameter',[0,12,0,6],[[48,46,50]]}, {'StatisticsParameter',[0,12,0,7],[[50,48]]}, {'StatisticsParameter',[0,12,0,8],[[52,48]]}]}]}}}]}]}}}]}}}
The size of the encoded values was 458 bytes for GUI
and 464 bytes for MEDIA-GATEWAY-CONTROL
.
Results
The ASN.1 specifications in the test were compiled with options ber_bin, optimize, driver
and asn1config
. Omitting option driver
gives higher values for decode
and decode_part
. These tests have not been rerun using NIFs, but are expected to perform about 5% better than the linked-in driver.
The test program runs 10000 decodes on the value, resulting in an output with the elapsed time in microseconds for the total number of decodes.
Function | Time (microseconds) | Decode Type | ASN.1 Specification | % of Time versus Complete Decode |
decode_MegacoMessage_selective/1 | 374045 | Selective | MEDIA-GATEWAY-CONTROL | 8.3 |
decode_MegacoMessage_exclusive/1 | 621107 | Exclusive | MEDIA-GATEWAY-CONTROL | 13.8 |
decode/2 | 4507457 | Complete | MEDIA-GATEWAY-CONTROL | 100 |
selected_decode_Window1/1 | 449585 | Selective | GUI | 7.6 |
selected_decode_Window2/1 | 890666 | Selective | GUI | 15.1 |
decode_Window_status_exclusive/1 | 1251878 | Exclusive | GUI | 21.3 |
decode/2 | 5889197 | Complete | GUI | 100 |
It is also of interest to know the relation is between a complete decode, an exclusive decode followed by decode_part
of the excluded parts, and a selective decode followed by a complete decode. Some situations can be compared to this simulation, for example, inspect a subvalue and later inspect the entire value. The following table shows figures from this test. The number of loops and the time unit are the same as in the previous test.
Actions | Function | Time (microseconds) | ASN.1 Specification | % of Time vs. Complete Decode |
Complete | decode/2 | 4507457 | MEDIA-GATEWAY-CONTROL | 100 |
Selective and Complete | decode_MegacoMessage_selective/1 | 4881502 | MEDIA-GATEWAY-CONTROL | 108.3 |
Exclusive and decode_part | decode_MegacoMessage_exclusive/1 | 5481034 | MEDIA-GATEWAY-CONTROL | 112.3 |
Complete | decode/2 | 5889197 | GUI | 100 |
Selective and Complete | selected_decode_Window1/1 | 6337636 | GUI | 107.6 |
Selective and Complete | selected_decode_Window2/1 | 6795319 | GUI | 115.4 |
Exclusive and decode_part | decode_Window_status_exclusive/1 | 6249200 | GUI | 106.1 |
Other ASN.1 types and values can differ much from these figures. It is therefore important that you, in every case where you intend to use either of these decodes, perform some tests that show if you will benefit your purpose.
Final Remarks
- The gain of using selective and exclusive decode instead of a complete decode is greater the bigger the value and the less deep in the structure you have to decode.
- Use selective decode instead of exclusive decode if you are interested in only a single subvalue.
- Exclusive decode followed by
decode_part
decodes is attractive if the parts are sent to different servers for decoding, or if you in some cases are not interested in all parts. - The fastest selective decode is when the decoded type is a primitive type and not so deep in the structure of the top type.
selected_decode_Window2
decodes a high constructed value, which explains why this operation is relatively slow. - It can vary from case to case which combination of selective/complete decode or exclusive/part decode is the fastest.
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Licensed under the Apache License, Version 2.0.