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Current Path : /proc/thread-self/root/usr/include/fstrm/ |
Current File : //proc/thread-self/root/usr/include/fstrm/control.h |
/* * Copyright (c) 2014 by Farsight Security, Inc. * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * */ #ifndef FSTRM_CONTROL_H #define FSTRM_CONTROL_H /** * \defgroup fstrm_control fstrm_control * * `fstrm_control` is an interface for encoding and decoding Frame Streams * control frames. * * Two types of frames are possible in a Frame Streams byte stream: **data * frames** and **control frames**. Both are variable length byte sequences * prefixed by a 32-bit big endian unsigned integer (the **frame length**) * specifying the length of the following byte sequence. If this frame length * value is greater than zero, the **frame length** specifies the **data frame * length**, and a data frame follows it. If the frame length is zero (i.e., it * is the four byte sequence `00 00 00 00`), this is an **escape sequence**, * which means that a control frame follows. The control frame itself is * prefixed by a 32-bit big endian unsigned integer (the **control frame * length**) specifying the length of the following **control frame payload**. * * There are two types of control frames used for uni-directional streams: * `START` and `STOP`. These control frame types bracket the stream of data * frames. `START` indicates the beginning of the stream and communicates * metadata about the stream to follow, and `STOP` indicates the end of the * stream. * * Bi-directional streams make use of three additional control frame types: * `READY`, `ACCEPT`, and `FINISH`. These control frame types are used in a * simple handshake protocol between sender and receiver. * * A uni-directional Frame Streams byte stream normally consists of the * following: * * 1. The `START` control frame. * 2. A sequence of zero or more data frames or control frames that are not of * the control frame types `START`, `STOP`, `ACCEPT`, `READY`, or * `FINISH`. * 3. The `STOP` control frame. * * The `START` and `STOP` control frames are not optional. The `START` control * frame must appear at the beginning of the byte stream, and the `STOP` control * frame must appear at the end of the byte stream. (If the byte stream has an * end.) `START` control frames must not appear anywhere other than at the * beginning of the byte stream, and `STOP` control frames must not appear * anywhere other than at the end of the byte stream. Only one `START` control * frame and only one `STOP` control frame may appear in a Frame Streams byte * stream. * * Control frames may optionally include zero or more **control frame fields**. * There is currently one type of control frame field defined: `CONTENT_TYPE`. * This field specifies a variable length byte sequence describing the encoding * of data frames that appear in the Frame Streams byte stream. This field is * used by cooperating programs to unambiguously identify how to interpret the * data frames in a particular Frame Streams byte stream. For instance, this * field may specify a particular schema to use to interpret the data frames * appearing in the byte stream. Zero, one, or more `CONTENT_TYPE` fields may * appear in `READY` or `ACCEPT` control frames. Zero or one `CONTENT_TYPE` * fields may appear in `START` control frames. No `CONTENT_TYPE` fields may * appear in `STOP` or `FINISH` control frames. * * A uni-directional Frame Streams encoder would normally produce a byte stream * as follows: * * 1. Write the `START` **control frame**. * + At the start of the byte stream, write the four byte **escape * sequence** `00 00 00 00` that precedes control frames. * + Write the **control frame length** as a 32-bit big endian unsigned * integer. * + Write the **control frame payload**. It must be a `START` control * frame. It may optionally specify a `CONTENT_TYPE` field. * 2. Write zero or more **data frames**. * 3. Write the `STOP` **control frame**. * + At the start of the byte stream, write the four byte **escape * sequence** `00 00 00 00` that precedes control frames. * + Write the **control frame length** as a 32-bit big endian unsigned * integer. * + Write the **control frame payload**. It must be a `STOP` control * frame. * * A uni-directional Frame Streams decoder would normally process the byte * stream as follows: * * 1. Read the `START` control frame. * + At the start of the byte stream, read the four byte **escape * sequence** `00 00 00 00` that precedes control frames. * + Read the 32-bit big endian unsigned integer specifying the **control * frame length**. * + Decode the **control frame payload**. It must be a `START` control * frame. It may optionally specify a `CONTENT_TYPE` field. * 2. Repeatedly read data frames or control frames following the `START` * control frame. * + Read the **frame length**, a 32-bit big endian unsigned integer. * + If the **frame length** is zero, a control frame follows: * + Read the 32-bit big endian unsigned integer specifying the * **control frame length**. * + Decode the **control frame payload**. If it is a `STOP` * control frame, the end of the Frame Streams byte stream has * occurred, and no frames follow. Break out of the decoding loop * and halt processing. (`READY`, `ACCEPT`, `START`, and `FINISH` * may not occur here. For forward compatibility, control frames of * types other than the types `READY`, `ACCEPT`, `START`, `STOP`, * and `FINISH` must be ignored here. No control frames specified * in the future may alter the encoding of succeeding frames.) * + If the **frame length** is non-zero, it specifies the number of bytes * in the following **data frame**. Consume these bytes from the byte * stream. * * The functions fstrm_control_encode() and fstrm_control_decode() are provided * to encode and decode control frames. See the detailed descriptions of those * functions for code examples showing their usage. * * @{ */ /** * The maximum length in bytes of an "Accept", "Start", or "Stop" control frame * payload. This excludes the escape sequence and the control frame length. */ #define FSTRM_CONTROL_FRAME_LENGTH_MAX 512 /** * The maximum length in bytes of a "Content Type" control frame field payload. * This excludes the field type and payload length. */ #define FSTRM_CONTROL_FIELD_CONTENT_TYPE_LENGTH_MAX 256 /** * Control frame types. */ typedef enum { /** Control frame type value for "Accept" control frames. */ FSTRM_CONTROL_ACCEPT = 0x01, /** Control frame type value for "Start" control frames. */ FSTRM_CONTROL_START = 0x02, /** Control frame type value for "Stop" control frames. */ FSTRM_CONTROL_STOP = 0x03, /** Control frame type value for "Ready" control frames. */ FSTRM_CONTROL_READY = 0x04, /** Control frame type value for "Finish" control frames. */ FSTRM_CONTROL_FINISH = 0x05, } fstrm_control_type; /** * Control frame field types. These are optional fields that can appear in * control frames. */ typedef enum { /** * Control frame field type value for the "Content Type" control frame * option. */ FSTRM_CONTROL_FIELD_CONTENT_TYPE = 0x01, } fstrm_control_field; /** * Flags for controlling the behavior of the encoding and decoding functions. */ typedef enum { /** * Set to control whether to include the control frame header in * encoding/decoding operations. * * Causes fstrm_control_encode() and fstrm_control_encoded_size() to * include the control frame header containing the escape sequence and * control frame payload length in the encoded output. Otherwise, only * the control frame payload itself is encoded. * * Tells fstrm_control_decode() that the input buffer to be decoded * begins with the control frame header containing the escape sequence * and control frame payload length. (Note that this requires the caller * to peek at the input buffer to calculate the right buffer length.) * Otherwise, the input buffer begins with the control frame payload. */ FSTRM_CONTROL_FLAG_WITH_HEADER = (1 << 0), } fstrm_control_flag; /** * Convert an `fstrm_control_type` enum value to a string representation. * Unknown values are represented as `"FSTRM_CONTROL_UNKNOWN"`. * * \param type The `fstrm_control_type` enum value. * \return The string representation of the enum value. (Always non-NULL.) */ const char * fstrm_control_type_to_str(fstrm_control_type type); /** * Convert an `fstrm_control_field` enum value to a string representation. * Unknown values are represented as `"FSTRM_CONTROL_FIELD_UNKNOWN"`. * * \param f_type The `fstrm_control_field` enum value. * \return The string representation of the enum value. (Always non-NULL.) */ const char * fstrm_control_field_type_to_str(fstrm_control_field f_type); /** * Initialize an `fstrm_control` object. This object represents Frame Streams * control frames and is used for encoding and decoding control frames. * * \return * An `fstrm_control` object. */ struct fstrm_control * fstrm_control_init(void); /** * Destroy an `fstrm_control` object. * * \param[in] c * Pointer to an `fstrm_control` object. */ void fstrm_control_destroy(struct fstrm_control **c); /** * Reinitialize an `fstrm_control` object. This resets the internal state to * default values. * * \param c * `fstrm_control` object. */ void fstrm_control_reset(struct fstrm_control *c); /** * Retrieve the type of the control frame. * * \param c * `fstrm_control` object. * \param[out] type * Type of the control frame. * * \retval #fstrm_res_success * \retval #fstrm_res_failure */ fstrm_res fstrm_control_get_type( const struct fstrm_control *c, fstrm_control_type *type); /** * Set the type of the control frame. * * \param c * `fstrm_control` object. * \param[in] type * Type of the control frame. * * \retval #fstrm_res_success * \retval #fstrm_res_failure */ fstrm_res fstrm_control_set_type( struct fstrm_control *c, fstrm_control_type type); /** * Retrieve the number of "Content Type" fields present in the control frame. * * \param c * `fstrm_control` object. * \param[out] n_content_type * The number of "Content Type" fields. * * \retval #fstrm_res_success * \retval #fstrm_res_failure */ fstrm_res fstrm_control_get_num_field_content_type( const struct fstrm_control *c, size_t *n_content_type); /** * Retrieve a "Content Type" field from the control frame. This function * returns a reference which must not be modified. Control frames may contain * zero, one, or more "Content Type" fields. * * \see fstrm_control_get_num_field_content_type() * * \param c * `fstrm_control` object. * \param[in] idx * The index of the "Content Type" field to retrieve. * \param[out] content_type * Pointer to where the reference to the "Content Type" string will be * stored. Note that this string is not NUL-terminated and may contain * embedded NULs. * \param[out] len_content_type * The number of bytes in `content_type`. * * \retval #fstrm_res_success * The control frame has a "Content Type" field. * \retval #fstrm_res_failure * The control frame does not have a "Content Type" field. */ fstrm_res fstrm_control_get_field_content_type( const struct fstrm_control *c, const size_t idx, const uint8_t **content_type, size_t *len_content_type); /** * Add a "Content Type" field to the control frame. This function makes a copy * of the provided string. This function may be called multiple times, in which * case multiple "Content Type" fields will be added to the control frame. * * The "Content Type" fields are removed on a call to fstrm_control_reset(). * * \param c * `fstrm_control` object. * \param[in] content_type * The "Content Type" string to copy. Note that this string is not * NUL-terminated and may contain embedded NULs. * \param[in] len_content_type * The number of bytes in `content_type`. * * \retval #fstrm_res_success * The "Content Type" field was successfully added. * \retval #fstrm_res_failure * The "Content Type" string is too long. */ fstrm_res fstrm_control_add_field_content_type( struct fstrm_control *c, const uint8_t *content_type, size_t len_content_type); /** * Check if the control frame matches a particular content type value. That is, * the content type given in the `match` and `len_match` parameters is checked * for compatibility with the content types (if any) specified in the control * frame. * * \param c * `fstrm_control` object. * \param match * The "Content Type" string to match. Note that this string is not * NUL-terminated and may contain embedded NULs. May be NULL, in which case * the control frame must not have any content type fields in order to * match. * \param len_match * The number of bytes in `match`. * * \retval #fstrm_res_success * A match was found. * \retval #fstrm_res_failure * A match was not found. */ fstrm_res fstrm_control_match_field_content_type( const struct fstrm_control *c, const uint8_t *match, const size_t len_match); /** * Decode a control frame from a buffer. The buffer starts with either the * escape sequence or the control frame payload depending on whether the * `FSTRM_CONTROL_FLAG_WITH_HEADER` flag is set or not. In either case, the * 'len_control_frame' parameter must be exact. Underflow or overflow is not * permitted. * * The following code example shows a function that decodes a control frame * payload: ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ static fstrm_res decode_control_frame(const void *control_frame, size_t len_control_frame) { fstrm_res res; fstrm_control_type c_type; struct fstrm_control *c; uint32_t flags = 0; c = fstrm_control_init(); res = fstrm_control_decode(c, control_frame, len_control_frame, flags); if (res != fstrm_res_success) { puts("fstrm_control_decode() failed."); fstrm_control_destroy(&c); return res; } res = fstrm_control_get_type(c, &c_type); if (res != fstrm_res_success) { puts("fstrm_control_get_type() failed."); fstrm_control_destroy(&c); return res; } printf("The control frame is of type %s (%u).\n", fstrm_control_type_to_str(c_type), c_type); size_t n_content_type; res = fstrm_control_get_num_field_content_type(c, &n_content_type); if (res != fstrm_res_success) { puts("fstrm_control_get_num_field_content_type() failed."); fstrm_control_destroy(&c); return res; } const uint8_t *content_type; size_t len_content_type; for (size_t idx = 0; idx < n_content_type; idx++) { res = fstrm_control_get_field_content_type(c, idx, &content_type, &len_content_type); if (res == fstrm_res_success) { printf("The control frame has a CONTENT_TYPE field of length %zd.\n", len_content_type); } } fstrm_control_destroy(&c); return fstrm_res_success; } ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * \param c * `fstrm_control` object. Its state will be overwritten. * \param[in] control_frame * Buffer containing the serialized control frame. * \param[in] len_control_frame * The number of bytes in `control_frame`. This parameter must specify the * exact number of bytes in the control frame. * \param flags * Flags controlling the decoding process. See #fstrm_control_flag. * * \retval #fstrm_res_success * \retval #fstrm_res_failure */ fstrm_res fstrm_control_decode( struct fstrm_control *c, const void *control_frame, size_t len_control_frame, const uint32_t flags); /** * Calculate the number of bytes needed to serialize the control frame. * * \param c * `fstrm_control` object. * \param[out] len_control_frame * The number of bytes needed to encode `c`. * \param flags * Flags controlling the encoding process. See #fstrm_control_flag. * * \retval #fstrm_res_success * \retval #fstrm_res_failure */ fstrm_res fstrm_control_encoded_size( const struct fstrm_control *c, size_t *len_control_frame, const uint32_t flags); /** * Encode a control frame into a buffer. Since a Frame Streams control frame is * a variable length byte sequence of up to #FSTRM_CONTROL_FRAME_LENGTH_MAX * bytes, this function can be used in two different ways. The first way is to * call fstrm_control_encoded_size() to obtain the exact number of bytes needed * to encode the frame, and then pass a buffer of this exact size to * fstrm_control_encode(). The following example shows this usage: ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ fstrm_res res; struct fstrm_control *c; uint8_t *control_frame; size_t len_control_frame; uint32_t flags = 0; c = fstrm_control_init(); res = fstrm_control_set_type(c, FSTRM_CONTROL_START); if (res != fstrm_res_success) { // Error handling goes here. } // Calculate the number of bytes needed. res = fstrm_control_encoded_size(c, &len_control_frame, flags); if (res != fstrm_res_success) { // Error handling goes here. } // 'len_control_frame' now specifies the number of bytes required for // the control frame. Allocate the needed space. control_frame = malloc(len_control_frame); if (!control_frame) { // Error handling goes here. } // Serialize the control frame into the allocated buffer. res = fstrm_control_encode(c, control_frame, &len_control_frame, 0); if (res != fstrm_res_success) { // Error handling goes here. } // Do something with 'control_frame' and 'len_control_frame'. // Clean up. free(control_frame); fstrm_control_destroy(&c); ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * The second way to use fstrm_control_encode() is to allocate a statically * sized buffer of #FSTRM_CONTROL_FRAME_LENGTH_MAX bytes. The exact number of * bytes serialized by the encoder will be returned in the `len_control_frame` * parameter. The following example shows this usage: ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ fstrm_res res; struct fstrm_control *c; uint8_t control_frame[FSTRM_CONTROL_FRAME_LENGTH_MAX]; size_t len_control_frame = sizeof(control_frame); c = fstrm_control_init(); res = fstrm_control_set_type(c, FSTRM_CONTROL_START); if (res != fstrm_res_success) { // Error handling. } // Serialize the control frame. res = fstrm_control_encode(c, control_frame, &len_control_frame, 0); if (res != fstrm_res_success) { // Error handling goes here. } // Do something with 'control_frame' and 'len_control_frame'. // Clean up. fstrm_control_destroy(&c); ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * \param c * `fstrm_control` object. * \param[out] control_frame * The buffer in which to serialize the control frame. * \param[in,out] len_control_frame * The size in bytes of `control_frame`. On a successful return, contains * the number of bytes actually written into `control_frame`. * \param flags * Flags controlling the encoding process. See #fstrm_control_flag. * * \retval #fstrm_res_success * \retval #fstrm_res_failure */ fstrm_res fstrm_control_encode( const struct fstrm_control *c, void *control_frame, size_t *len_control_frame, const uint32_t flags); /**@}*/ #endif /* FSTRM_CONTROL_H */