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@ -1,26 +1,23 @@ |
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# TinyFrame |
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TinyFrame is a simple library for building and parsing data frames to be sent |
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over a serial interface (e.g. UART, telnet etc.). The code is written to build with |
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`--std=gnu89` and later. |
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over a serial interface (e.g. UART, telnet, socket). The code is written to build with |
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`--std=gnu99` and mostly compatible with `--std=gnu89`. |
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The library provides a high level interface for passing messages between the two peers. |
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Multi-message sessions, response listeners, checksums, timeouts are all handled by the library. |
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TinyFrame is suitable for a wide range of applications, including inter-microcontroller |
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communication, as a protocol for FTDI-based PC applications or for messaging through |
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UDP packets. If you find a good use for it, please let me know so I can add it here! |
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Frames can be protected by a checksum (~XOR, CRC16 or CRC32) and contain |
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a unique ID field which can be used for chaining related messages. The highest bit |
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of the generated frame IDs is different in each peer to avoid collisions. |
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Peers are functionally equivalent and can send messages to each other |
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(the names "master" and "slave" are used only for convenience). |
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UDP packets. |
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The library lets you register listeners (callback functions) to wait for (1) any frame, (2) |
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a particular frame Type, or (3) a specific message ID. This high-level API lets the user |
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easily implement various async communication patterns. |
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a particular frame Type, or (3) a specific message ID. This high-level API is general |
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enough to implement most communication patterns. |
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TinyFrame is re-entrant and supports creating multiple instances with the limitation |
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that their structure (field sizes and checksum type) must be the same. There is a support |
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for adding multi-threaded access to a shared instance using a mutex (via a callback stub). |
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that their structure (field sizes and checksum type) is the same. There is a support |
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for adding multi-threaded access to a shared instance using a mutex. |
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TinyFrame also comes with (optional) helper functions for building and parsing message |
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payloads, those are provided in the `utils/` folder. |
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@ -34,18 +31,30 @@ TinyFrame has been ported to mutiple languages: |
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- Rust port - [cpsdqs/tinyframe-rs](https://github.com/cpsdqs/tinyframe-rs) |
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- JavaScript port - [cpsdqs/tinyframe-js](https://github.com/cpsdqs/tinyframe-js) |
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Please note most of the ports are experimental and may exhibit various bugs or missing features. Testers are welcome :) |
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Please note most of the ports are experimental and may exhibit various bugs or missing |
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features. Testers are welcome :) |
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## Functional overview |
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The basic functionality of TinyFrame is explained here. For particlars, such as the |
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API function, it's recommended to read the doc comments in the header file. |
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## Frame structure |
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### Structure of a frame |
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All fields in the message frame have a configurable size (see the top of the header file). |
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By just changing a definition in the header, such as `TF_LEN_BYTES` (1, 2 or 4), the library |
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seamlessly switches between `uint8_t`, `uint16_t` and `uint32_t`. Choose field lengths that |
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best suit your application needs. |
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Each frame consists of a header and a payload. Both parts can be protected by a checksum, |
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ensuring a frame with a malformed header (e.g. with a corrupted length field) or a corrupted |
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payload is rejected. |
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For example, you don't need 4 bytes (`uint32_t`) for the |
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length field if your payloads are 20 bytes long, using a 1-byte field (`uint8_t`) will save |
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3 bytes. This may be significant if you need high throughput. |
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The frame header contains a frame ID and a message type. Frame ID is incremented with each |
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new message. The highest bit of the ID field is fixed to 1 and 0 for the two peers, |
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avoiding a conflict. |
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Frame ID can be re-used in a response to tie the two messages together. Values of the |
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type field are user defined. |
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All fields in the frame have a configurable size. By changing a field in the config |
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file, such as `TF_LEN_BYTES` (1, 2 or 4), the library seamlessly switches between `uint8_t`, |
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`uint16_t` and `uint32_t` for all functions working with the field. |
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``` |
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,-----+-----+-----+------+------------+- - - -+-------------, |
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@ -59,17 +68,69 @@ LEN ......... number of data bytes in the frame |
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TYPE ........ message type (used to run Type Listeners, pick any values you like) |
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HEAD_CKSUM .. header checksum |
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DATA ........ LEN bytes of data (can be 0, in which case DATA_CKSUM is omitted as well) |
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DATA_CKSUM .. data checksum |
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DATA ........ LEN bytes of data |
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DATA_CKSUM .. data checksum (left out if LEN is 0) |
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``` |
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### Message listeners |
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TinyFrame is based on the concept of message listeners. A listener is a callback function |
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waiting for a particular message Type or ID to be received. |
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There are 3 listener types, in the order of precedence: |
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- **ID listeners** - waiting for a response |
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- **Type listeners** - waiting for a message of the given Type field |
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- **Generic listeners** - fallback |
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ID listeners can be registered automatically when sending a message. All listeners can |
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also be registered and removed manually. |
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ID listeners are used to receive the response to a request. When registerign an ID |
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listener, it's possible to attach custom user data to it that will be made available to |
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the listener callback. This data (`void *`) can be any kind of application context |
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variable. |
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ID listeners can be assigned a timeout. When a listener expires, before it's removed, |
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the callback is fired with NULL payload data in order to let the user `free()` any |
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attached userdata. This happens only if the userdata is not NULL. |
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Listener callbacks return values of the `TF_Result` enum: |
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- `TF_CLOSE` - message accepted, remove the listener |
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- `TF_STAY` - message accepted, stay registered |
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- `TF_RENEW` - sameas `TF_STAY`, but the ID listener's timeout is renewed |
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- `TF_NEXT` - message NOT accepted, keep the listener and pass the message to the next |
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listener capable of handling it. |
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### Data buffers, multi-part frames |
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TinyFrame uses two data buffers: a small transmit buffer and a larger receive buffer. |
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The transmit buffer is used to prepare bytes to send, either all at once, or in a |
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circular fashion if the buffer is not large enough. The buffer must be large enough to |
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contain the frame header, so e.g. 32 bytes should be sufficient for short messages. |
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Using the `*_Multipart()` sending functions, it's further possible to split the frame |
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header and payload to multiple function calls, allowing the applciation to e.g. generate |
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the payload on-the-fly. |
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In contrast to the transmit buffer, the receive buffer must be large enough to contain |
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an entire frame. This is because the final checksum must be verified before the frame |
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is handled. |
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If frames larger than the possible receive buffer size are required (e.g. in embedded |
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systems with small RAM), it's recommended to implement a multi-message transport mechanism |
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at a higher level and send the data in chunks. |
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## Usage Hints |
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- All TinyFrame functions, typedefs and macros start with the `TF_` prefix. |
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- Both peers must include the library with the same parameters (configured at the top of the header file) |
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- Both peers must include the library with the same config parameters |
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- See `TF_Integration.example.c` and `TF_Config.example.c` for reference how to configure and integrate the library. |
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- DO NOT modify the library files, if possible. This makes it easy to upgrade. |
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- Start by calling `TF_Init()` with `TF_MASTER` or `TF_SLAVE` as the argument. This creates a handle. |
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Use `TF_InitStatic()` to avoid the use of malloc(). If multiple instances are used, you can tag them |
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using the `tf.userdata` / `tf.usertag` field. |
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Use `TF_InitStatic()` to avoid the use of malloc(). |
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- If multiple instances are used, you can tag them using the `tf.userdata` / `tf.usertag` field. |
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- Implement `TF_WriteImpl()` - declared at the bottom of the header file as `extern`. |
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This function is used by `TF_Send()` and others to write bytes to your UART (or other physical layer). |
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A frame can be sent in it's entirety, or in multiple parts, depending on its size. |
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@ -78,25 +139,30 @@ DATA_CKSUM .. data checksum |
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in a bad state (such as receiving a partial frame) and can also time-out ID listeners. |
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- Bind Type or Generic listeners using `TF_AddTypeListener()` or `TF_AddGenericListener()`. |
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- Send a message using `TF_Send()`, `TF_Query()`, `TF_SendSimple()`, `TF_QuerySimple()`. |
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Query functions take a listener callback (function pointer)that will be added as |
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Query functions take a listener callback (function pointer) that will be added as |
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an ID listener and wait for a response. |
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- Use the `*_Multipart()` variant of the above sending functions for payloads generated in |
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multiple function calls. The payload is sent afterwards by calling `TF_Multipart_Payload()` |
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and the frame is closed by `TF_Multipart_Close()`. |
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- If custom checksum implementation is needed, select `TF_CKSUM_CUSTOM8`, 16 or 32 and |
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implement the three checksum functions. |
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- To reply to a message (when your listener gets called), use `TF_Respond()` |
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with the msg boject you received, replacing the `data` pointer (and `len`) with response. |
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- Manually reset the parser using `TF_ResetParser()` |
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### Message listeners |
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Listeners are callback functions that are called by TinyFrame when a message which |
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they can handle is received. |
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There are 3 listener types: |
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- ID listeners |
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- Type listeners |
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- Generic listeners |
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Listeners return an enum constant based on what should be done next - remove the listener, |
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keep it, renew it's timeout, or let some other listener handle the message. |
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with the msg object you received, replacing the `data` pointer (and `len`) with a response. |
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- At any time you can manually reset the message parser using `TF_ResetParser()`. It can also |
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be reset automatically after a timeout configured in the config file. |
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### Gotchas to look out for |
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- If any userdata is attached to an ID listener with a timeout, when the listener times out, |
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it will be called with NULL `msg->data` to let the user free the userdata. Therefore |
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it's needed to check `msg->data` before proceeding to handle the message. |
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- If a multi-part frame is being sent, the Tx part of the library is locked to prevent |
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concurrent access. The frame must be fully sent and closed before attempting to send |
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anything else. |
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- If multiple threads are used, don't forget to implement the mutex callbacks to avoid |
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concurrent access to the Tx functions. The default implementation is not entirely thread |
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safe, as it can't rely on platform-specific resources like mutexes or atomic access. |
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Set `TF_USE_MUTEX` to `1` in the config file. |
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### Examples |
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