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authorNathan Skrzypczak <nathan.skrzypczak@gmail.com>2021-10-08 14:01:27 +0200
committerDave Wallace <dwallacelf@gmail.com>2021-10-13 15:32:33 +0000
commitd4a70647e6b8de2cb81cbea3c53d08c299b65cc5 (patch)
tree4c9e695232b110ea95326ecb86f706d34c065289 /src/tools/vppapigen
parenta2c9509a4ab22380937a2b613fcc518da22f5166 (diff)
docs: convert vpp doc md->rst
Type: improvement Change-Id: If453321785b04f9c16e8cea36fb1910efaeb2c59 Signed-off-by: Nathan Skrzypczak <nathan.skrzypczak@gmail.com>
Diffstat (limited to 'src/tools/vppapigen')
-rw-r--r--src/tools/vppapigen/VPPAPI.md346
-rw-r--r--src/tools/vppapigen/VPPAPI.rst404
2 files changed, 404 insertions, 346 deletions
diff --git a/src/tools/vppapigen/VPPAPI.md b/src/tools/vppapigen/VPPAPI.md
deleted file mode 100644
index df211d866a0..00000000000
--- a/src/tools/vppapigen/VPPAPI.md
+++ /dev/null
@@ -1,346 +0,0 @@
-# VPP API Language {#api_lang_doc}
-
-The VPP binary API is a message passing API.
-The VPP API language is used to define a RPC interface between VPP and its
-control plane. The API messages supports shared memory transport and
-Unix domain sockets (SOCK_STREAM).
-
-The wire format is essentially that of a network formatted (big-endian) packed C struct.
-
-The VPP API compiler is located in *src/tools/vppapigen* and can currently
-compile to JSON or C (used by the VPP binary itself).
-
-## Language definition
-
-### Defining a messages
-
-There are 3 types of message exchanges:
-
-* Request/Reply
-The client sends a request message and the server replies with a
-single reply message. The convention is that the reply message is
-named as method_name + \_reply.
-
-* Dump/Detail
-The client sends a "bulk" request message to the server, and the
-server replies with a set of detail messages. These messages may be of
-different type. A dump/detail call must be enclosed in a control ping
-block (Otherwise the client will not know the end of the bulk
-transmission). The method name must end with method + "\_dump", the
-reply message should be named method + "\_details". The exception here
-is for the methods that return multiple message types
-(e.g. sw_interface_dump). The Dump/Detail methods are typically used
-for acquiring bulk information, like the complete FIB table.
-
-* Events
-The client can register for getting asynchronous notifications from
-the server. This is useful for getting interface state changes, and so
-on. The method name for requesting notifications is conventionally
-prefixed with "want_". E.g. "want_interface_events". Which
-notification types results from an event registration is defined in
-the service definition.
-
-A message from a client must include the 'client_index', an opaque
-cookie identifying the sender, and a 'context' field to let the client
-match request with reply.
-
-An example of a message definition. The client sends the show_version request,
-the server replies with the show_version_reply.
-
-The *client_index* and *context* fields are required in all requests.
-The *context* is returned by the server and is used by the client to
-match up request and reply messages.
-
-```
-define show_version
-{
- u32 client_index;
- u32 context;
-};
-define show_version_reply
-{
- u32 context;
- i32 retval;
- string program [32];
- string version [32];
- string build_date [32];
- /* The final field can be a variable length argument */
- string build_directory [];
-};
-
-```
-
-The flags are not used by the clients, but have special meaning
-for some of the tracing and debugging of the API.
-The *autoreply* flag is a shorthand for a reply message with just a
-*retval* field.
-
-```
- define : DEFINE ID '{' block_statements_opt '}' ';'
- define : flist DEFINE ID '{' block_statements_opt '}' ';'
- flist : flag
- | flist flag
- flag : MANUAL_PRINT
- | MANUAL_ENDIAN
- | DONT_TRACE
- | AUTOREPLY
-
- block_statements_opt : block_statements
- block_statements : block_statement
- | block_statements block_statement
- block_statement : declaration
- | option
- declaration : type_specifier ID ';'
- | type_specifier ID '[' ID '=' assignee ']' ';'
- declaration : type_specifier ID '[' NUM ']' ';'
- | type_specifier ID '[' ID ']' ';'
- type_specifier : U8
- | U16
- | U32
- | U64
- | I8
- | I16
- | I32
- | I64
- | F64
- | BOOL
- | STRING
- type_specifier : ID
-```
-
-
-### Options
-The *option* word is used to specify meta information.
-The only current use is to specify a semantic version of the .api file itself.
-
-Example:
-```
-option version = "1.0.0";
-```
-
-```
-
- option : OPTION ID '=' assignee ';'
- assignee : NUM
- | TRUE
- | FALSE
- | STRING_LITERAL
-```
-
-### Defining new types
-
-New user defined types are defined just like messages.
-A typedef has two forms. It can either define an alias for a
-different type (or array).
-
-Example:
-
-```
-typedef u8 ip4_address[4];
-typedef u8 ip6_address[16];
-```
-
-Where the above defines two new types *vl_api_ip4_address_t* and
-*vl_api_ip6_address_t*. These are aliases for the underlying
-u8 array.
-
-In the other form, it is used to specify an abstract data type.
-
-```
-enum address_family {
- ADDRESS_IP4 = 0,
- ADDRESS_IP6,
-};
-
-union address_union {
- vl_api_ip4_address_t ip4;
- vl_api_ip6_address_t ip6;
-};
-
-typedef address {
- vl_api_address_family_t af;
- vl_api_address_union_t un;
-};
-```
-
-Where the new type *vl_api_address_t*
-
-```
- typedef : TYPEDEF ID '{' block_statements_opt '}' ';'
- typedef : TYPEDEF declaration
-```
-
-
-### Importing Definitions
-You can use definitions from other .api files by importing them.
-To import another .api's definitions, you add an import statement
-to the top of your file:
-
-import "vnet/ip/ip_types.api";
-
-By default you can only use definitions from directly imported .api files.
-
-The API compiler searches for imported files in a set of directories
-specified on the API compiler command line using the --includedir flag.
-```
-import : IMPORT STRING_LITERAL ';'
-```
-
-### Comments
-
-The API language uses C style comments.
-```
-/* */
-//
-```
-
-### Enumerations
-Enums are similar to enums in C.
-
-Every enum definition must contain a constant that maps to zero
-as its first element. This is because:
-
-There must be a zero value, so that we can use 0 as a numeric default value.
-The zero value needs to be the first element.
-
-As in C, enums can be used as flags or just as numbers.
-The on-wire, and in memory representation size of an enum can be specified.
-Not all language bindings will support that. The default size is 4 (u32).
-
-Example
-```
-enum ip_neighbor_flags
-{
- IP_API_NEIGHBOR_FLAG_NONE = 0,
- IP_API_NEIGHBOR_FLAG_STATIC = 0x1,
- IP_API_NEIGHBOR_FLAG_NO_FIB_ENTRY = 0x2,
-};
-```
-
-Which generates the vl_api_ip_neighbor_flags_t in the C binding.
-In Python that is represented as an IntFlag object
-VppEnum.vl_api_ip_neighbor_flags_t.
-
-```
- enum : ENUM ID '{' enum_statements '}' ';'
- enum : ENUM ID ':' enum_size '{' enum_statements '}' ';'
- enum_size : U8
- | U16
- | U32
- enum_statements : enum_statement
- | enum_statements enum_statement
- enum_statement : ID '=' NUM ','
- | ID ','
-```
-
-### Services
-The service statement defines the relationship between messages.
-For request/response and dump/details messages it ties the
-request with the reply. For events, it specifies which events
-that can be received for a given want_* call.
-
-Example:
-```
-service {
- rpc want_interface_events returns want_interface_events_reply
- events sw_interface_event;
-};
-
-```
-
-Which states that the request want_interface_events returns a
-want_interface_events_reply and if enabled the client will
-receive sw_interface_event messages whenever interface states changes.
-
-```
- service : SERVICE '{' service_statements '}' ';'
- service_statements : service_statement
- | service_statements service_statement
- service_statement : RPC ID RETURNS NULL ';'
- | RPC ID RETURNS ID ';'
- | RPC ID RETURNS STREAM ID ';'
- | RPC ID RETURNS ID EVENTS event_list ';'
- event_list : events
- | event_list events
- events : ID
- | ID ','
-```
-
-
-## Types
-### Scalar Value Types
-
-.api type|size|C type|Python type
----------|----|------|-----------
-i8 | 1|i8 |int
-u8 | 1|u8 |int
-i16 | 2|i16 |int
-u16 | 2|u16 |int
-i32 | 4|i32 |int
-u32 | 4|u32 |int
-i64 | 8|i64 |int
-u64 | 8|u64 |int
-f64 | 8|f64 |float
-bool | 1|bool |boolean
-string |variable|vl_api_string_t|str
-
-### User Defined Types
-#### vnet/ip/ip_types.api
-
-.api type|size|C type|Python type
----------|----|------|-----------
-vl_api_address_t|20|vl_api_address_t|`<class 'ipaddress.IPv4Address'> or <class 'ipaddress.IPv6Address'>`
-vl_api_ip4_address_t|4|vl_api_ip4_address_t|`<class 'ipaddress.IPv4Address'>`
-vl_api_ip6_address_t|16|vl_api_ip6_address_t|`<class 'ipaddress.IPv6Address'>`
-vl_api_prefix_t|21|vl_api_prefix_t|`<class 'ipaddress.IPv4Network'> or <class 'ipaddress.IPv6Network'>`
-vl_api_ip4_prefix_t|5|vl_api_ip4_prefix_t|`<class 'ipaddress.IPv4Network'>`
-vl_api_ip6_prefix_t|17|vl_api_ip6_prefix_t|`<class 'ipaddress.IPv6Network'>`
-vl_api_ip4_address_with_prefix_t|5|vl_api_ip4_address_with_prefix_t|`<class 'ipaddress.IPv4Interface'>`
-vl_api_ip6_address_with_prefix_t|17|vl_api_ip6_address_with_prefix_t|`<class 'ipaddress.IPv6Interface'>`
-
-#### vnet/ethernet/ethernet_types.api
-.api type|size|C type|Python type
----------|----|------|-----------
-vl_api_mac_address_t|6|vl_api_mac_address_t|`class 'vpp_papi.MACAddress'>`
-
-#### vnet/interface_types.api
-.api type|size|C type|Python type
----------|----|------|-----------
-vl_api_interface_index_t|4|vl_api_interface_index_t|int
-
-### New explicit types
-
-#### String versus bytes
-A byte string with a maximum length of 64:
-```
-u8 name[64];
-```
-Before the "string" type was added, text string were defined like this.
-The implications of that was the user would have to know if the field
-represented a \0 ended C-string or a fixed length byte string.
-The wire format of the 'string' type is a u32 length
-
-An IPv4 or IPv6 address was previously defined like:
-```
-u8 is_ip6;
-u8 address[16];
-```
-
-Which made it hard for language bindings to represent the
-address as anything but a byte string.
-The new explicit address types are shown above.
-
-## Language generators
-
-The VPP API compiler currently has two output modules. One generating JSON
-and one generating C header files that are directly used by the VPP
-infrastructure and plugins.
-
-The C/C++, Python, Go Lua, and Java language bindings are generated based
-on the JSON files.
-
-### Future considerations
-- [ ] Generate C/C++ (vapi) client code directly from vppapigen
-- [ ] Embed JSON definitions into the API server, so dynamic languages
- can download them directly without going via the filesystem and JSON
- files.
diff --git a/src/tools/vppapigen/VPPAPI.rst b/src/tools/vppapigen/VPPAPI.rst
new file mode 100644
index 00000000000..5b172a8c758
--- /dev/null
+++ b/src/tools/vppapigen/VPPAPI.rst
@@ -0,0 +1,404 @@
+VPP API Language
+================
+
+The VPP binary API is a message passing API. The VPP API language is
+used to define a RPC interface between VPP and its control plane. The
+API messages supports shared memory transport and Unix domain sockets
+(SOCK_STREAM).
+
+The wire format is essentially that of a network formatted (big-endian)
+packed C struct.
+
+The VPP API compiler is located in *src/tools/vppapigen* and can
+currently compile to JSON or C (used by the VPP binary itself).
+
+Language definition
+-------------------
+
+Defining a messages
+~~~~~~~~~~~~~~~~~~~
+
+There are 3 types of message exchanges:
+
+- Request/Reply The client sends a request message and the server
+ replies with a single reply message. The convention is that the reply
+ message is named as method_name + \_reply.
+
+- Dump/Detail The client sends a “bulk” request message to the server,
+ and the server replies with a set of detail messages. These messages
+ may be of different type. A dump/detail call must be enclosed in a
+ control ping block (Otherwise the client will not know the end of the
+ bulk transmission). The method name must end with method + “\_dump”,
+ the reply message should be named method + “\_details”. The exception
+ here is for the methods that return multiple message types
+ (e.g. sw_interface_dump). The Dump/Detail methods are typically used
+ for acquiring bulk information, like the complete FIB table.
+
+- Events The client can register for getting asynchronous notifications
+ from the server. This is useful for getting interface state changes,
+ and so on. The method name for requesting notifications is
+ conventionally prefixed with “want\_”. E.g. “want_interface_events”.
+ Which notification types results from an event registration is
+ defined in the service definition.
+
+A message from a client must include the ‘client_index’, an opaque
+cookie identifying the sender, and a ‘context’ field to let the client
+match request with reply.
+
+An example of a message definition. The client sends the show_version
+request, the server replies with the show_version_reply.
+
+The *client_index* and *context* fields are required in all requests.
+The *context* is returned by the server and is used by the client to
+match up request and reply messages.
+
+.. code-block:: c
+
+ define show_version
+ {
+ u32 client_index;
+ u32 context;
+ };
+ define show_version_reply
+ {
+ u32 context;
+ i32 retval;
+ string program [32];
+ string version [32];
+ string build_date [32];
+ /* The final field can be a variable length argument */
+ string build_directory [];
+ };
+
+The flags are not used by the clients, but have special meaning for some
+of the tracing and debugging of the API. The *autoreply* flag is a
+shorthand for a reply message with just a *retval* field.
+
+.. code-block:: c
+
+ define : DEFINE ID '{' block_statements_opt '}' ';'
+ define : flist DEFINE ID '{' block_statements_opt '}' ';'
+ flist : flag
+ | flist flag
+ flag : MANUAL_PRINT
+ | MANUAL_ENDIAN
+ | DONT_TRACE
+ | AUTOREPLY
+
+ block_statements_opt : block_statements
+ block_statements : block_statement
+ | block_statements block_statement
+ block_statement : declaration
+ | option
+ declaration : type_specifier ID ';'
+ | type_specifier ID '[' ID '=' assignee ']' ';'
+ declaration : type_specifier ID '[' NUM ']' ';'
+ | type_specifier ID '[' ID ']' ';'
+ type_specifier : U8
+ | U16
+ | U32
+ | U64
+ | I8
+ | I16
+ | I32
+ | I64
+ | F64
+ | BOOL
+ | STRING
+ type_specifier : ID
+
+Options
+~~~~~~~
+
+The *option* word is used to specify meta information. The only current
+use is to specify a semantic version of the .api file itself.
+
+Example:
+
+.. code-block:: c
+
+ option version = "1.0.0";
+
+.. code-block:: c
+
+
+ option : OPTION ID '=' assignee ';'
+ assignee : NUM
+ | TRUE
+ | FALSE
+ | STRING_LITERAL
+
+Defining new types
+~~~~~~~~~~~~~~~~~~
+
+New user defined types are defined just like messages. A typedef has two
+forms. It can either define an alias for a different type (or array).
+
+Example:
+
+.. code-block:: c
+
+ typedef u8 ip4_address[4];
+ typedef u8 ip6_address[16];
+
+Where the above defines two new types *vl_api_ip4_address_t* and
+*vl_api_ip6_address_t*. These are aliases for the underlying u8 array.
+
+In the other form, it is used to specify an abstract data type.
+
+.. code-block:: c
+
+ enum address_family {
+ ADDRESS_IP4 = 0,
+ ADDRESS_IP6,
+ };
+
+ union address_union {
+ vl_api_ip4_address_t ip4;
+ vl_api_ip6_address_t ip6;
+ };
+
+ typedef address {
+ vl_api_address_family_t af;
+ vl_api_address_union_t un;
+ };
+
+Where the new type *vl_api_address_t*
+
+.. code-block:: c
+
+ typedef : TYPEDEF ID '{' block_statements_opt '}' ';'
+ typedef : TYPEDEF declaration
+
+Importing Definitions
+~~~~~~~~~~~~~~~~~~~~~
+
+You can use definitions from other .api files by importing them. To
+import another .api’s definitions, you add an import statement to the
+top of your file:
+
+import “vnet/ip/ip_types.api”;
+
+By default you can only use definitions from directly imported .api
+files.
+
+The API compiler searches for imported files in a set of directories
+specified on the API compiler command line using the –includedir flag.
+
+.. code-block:: c
+
+ import : IMPORT STRING_LITERAL ';'
+
+Comments
+~~~~~~~~
+
+The API language uses C style comments.
+
+.. code-block:: c
+
+ /* */
+ //
+
+Enumerations
+~~~~~~~~~~~~
+
+Enums are similar to enums in C.
+
+Every enum definition must contain a constant that maps to zero as its
+first element. This is because:
+
+There must be a zero value, so that we can use 0 as a numeric default
+value. The zero value needs to be the first element.
+
+As in C, enums can be used as flags or just as numbers. The on-wire, and
+in memory representation size of an enum can be specified. Not all
+language bindings will support that. The default size is 4 (u32).
+
+Example
+
+.. code-block:: c
+
+ enum ip_neighbor_flags
+ {
+ IP_API_NEIGHBOR_FLAG_NONE = 0,
+ IP_API_NEIGHBOR_FLAG_STATIC = 0x1,
+ IP_API_NEIGHBOR_FLAG_NO_FIB_ENTRY = 0x2,
+ };
+
+Which generates the vl_api_ip_neighbor_flags_t in the C binding. In
+Python that is represented as an IntFlag object
+VppEnum.vl_api_ip_neighbor_flags_t.
+
+.. code-block:: c
+
+ enum : ENUM ID '{' enum_statements '}' ';'
+ enum : ENUM ID ':' enum_size '{' enum_statements '}' ';'
+ enum_size : U8
+ | U16
+ | U32
+ enum_statements : enum_statement
+ | enum_statements enum_statement
+ enum_statement : ID '=' NUM ','
+ | ID ','
+
+Services
+~~~~~~~~
+
+The service statement defines the relationship between messages. For
+request/response and dump/details messages it ties the request with the
+reply. For events, it specifies which events that can be received for a
+given ``want_*`` call.
+
+Example:
+
+.. code-block:: c
+
+ service {
+ rpc want_interface_events returns want_interface_events_reply
+ events sw_interface_event;
+ };
+
+Which states that the request want_interface_events returns a
+want_interface_events_reply and if enabled the client will receive
+sw_interface_event messages whenever interface states changes.
+
+.. code-block:: c
+
+ service : SERVICE '{' service_statements '}' ';'
+ service_statements : service_statement
+ | service_statements service_statement
+ service_statement : RPC ID RETURNS NULL ';'
+ | RPC ID RETURNS ID ';'
+ | RPC ID RETURNS STREAM ID ';'
+ | RPC ID RETURNS ID EVENTS event_list ';'
+ event_list : events
+ | event_list events
+ events : ID
+ | ID ','
+
+Types
+-----
+
+Scalar Value Types
+~~~~~~~~~~~~~~~~~~
+
+========= ======== =============== ===========
+.api type size C type Python type
+========= ======== =============== ===========
+i8 1 i8 int
+u8 1 u8 int
+i16 2 i16 int
+u16 2 u16 int
+i32 4 i32 int
+u32 4 u32 int
+i64 8 i64 int
+u64 8 u64 int
+f64 8 f64 float
+bool 1 bool boolean
+string variable vl_api_string_t str
+========= ======== =============== ===========
+
+User Defined Types
+~~~~~~~~~~~~~~~~~~
+
+vnet/ip/ip_types.api
+^^^^^^^^^^^^^^^^^^^^
+
++--------------------+--------+-------------+-------------------------+
+| .api type | size | C type | Python type |
++====================+========+=============+=========================+
+| vl_api_address_t | 20 | vl_ap | ` |
+| | | i_address_t | `<class 'ipaddress.IPv4 |
+| | | | Address'> or <class 'ip |
+| | | | address.IPv6Address'>`` |
++--------------------+--------+-------------+-------------------------+
+| vl | 4 | vl_api_ip | ``<class 'ip |
+| _api_ip4_address_t | | 4_address_t | address.IPv4Address'>`` |
++--------------------+--------+-------------+-------------------------+
+| vl | 16 | vl_api_ip | ``<class 'ip |
+| _api_ip6_address_t | | 6_address_t | address.IPv6Address'>`` |
++--------------------+--------+-------------+-------------------------+
+| vl_api_prefix_t | 21 | vl_a | ` |
+| | | pi_prefix_t | `<class 'ipaddress.IPv4 |
+| | | | Network'> or <class 'ip |
+| | | | address.IPv6Network'>`` |
++--------------------+--------+-------------+-------------------------+
+| v | 5 | vl_api_i | ``<class 'ip |
+| l_api_ip4_prefix_t | | p4_prefix_t | address.IPv4Network'>`` |
++--------------------+--------+-------------+-------------------------+
+| v | 17 | vl_api_i | ``<class 'ip |
+| l_api_ip6_prefix_t | | p6_prefix_t | address.IPv6Network'>`` |
++--------------------+--------+-------------+-------------------------+
+| vl_api_ip4_add | 5 | vl_api_ip4 | ``<class 'ipad |
+| ress_with_prefix_t | | _address_wi | dress.IPv4Interface'>`` |
+| | | th_prefix_t | |
++--------------------+--------+-------------+-------------------------+
+| vl_api_ip6_add | 17 | vl_api_ip6 | ``<class 'ipad |
+| ress_with_prefix_t | | _address_wi | dress.IPv6Interface'>`` |
+| | | th_prefix_t | |
++--------------------+--------+-------------+-------------------------+
+
+vnet/ethernet/ethernet_types.api
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+
++---------------------+------+---------------------+-------------------+
+| .api type | size | C type | Python type |
++=====================+======+=====================+===================+
+| ``vl_ | 6 | ``vl_ | ``class 'vpp_pa |
+| api_mac_address_t`` | | api_mac_address_t`` | pi.MACAddress'>`` |
++---------------------+------+---------------------+-------------------+
+
+vnet/interface_types.api
+^^^^^^^^^^^^^^^^^^^^^^^^
+
+======================== ==== ======================== ===========
+.api type size C type Python type
+======================== ==== ======================== ===========
+vl_api_interface_index_t 4 vl_api_interface_index_t int
+======================== ==== ======================== ===========
+
+New explicit types
+~~~~~~~~~~~~~~~~~~
+
+String versus bytes
+^^^^^^^^^^^^^^^^^^^
+
+A byte string with a maximum length of 64:
+
+.. code-block:: c
+
+ u8 name[64];
+
+Before the “string” type was added, text string were defined like this.
+The implications of that was the user would have to know if the field
+represented a \\0 ended C-string or a fixed length byte string. The wire
+format of the ‘string’ type is a u32 length
+
+An IPv4 or IPv6 address was previously defined like:
+
+.. code-block:: c
+
+ u8 is_ip6;
+ u8 address[16];
+
+Which made it hard for language bindings to represent the address as
+anything but a byte string. The new explicit address types are shown
+above.
+
+Language generators
+-------------------
+
+The VPP API compiler currently has two output modules. One generating
+JSON and one generating C header files that are directly used by the VPP
+infrastructure and plugins.
+
+The C/C++, Python, Go Lua, and Java language bindings are generated
+based on the JSON files.
+
+Future considerations
+~~~~~~~~~~~~~~~~~~~~~
+
+- Generate C/C++ (vapi) client code directly from vppapigen
+- Embed JSON definitions into the API server, so dynamic languages
+ can download them directly without going via the filesystem and JSON
+ files.