dynamo-runtime 1.3.0-dev.1

// SPDX-FileCopyrightText: Copyright (c) 2024-2026 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
// SPDX-License-Identifier: Apache-2.0

//! Zero-copy TCP message decoder for high-concurrency scenarios
//!
//! This decoder eliminates message reconstruction copies by:
//! 1. Reading into a reusable buffer
//! 2. Parsing headers in-place
//! 3. Splitting off exact message sizes (zero-copy via Bytes::split_to)
//! 4. Returning Arc-counted Bytes that can be cloned cheaply

use super::{
    check_tcp_request_max_message_size, parse_tcp_request_frame_header, tcp_request_endpoint_len,
    tcp_request_header_size, tcp_request_headers_len,
};
use crate::pipeline::network::get_tcp_max_message_size;
use bytes::{Bytes, BytesMut};
use std::io;
use std::sync::OnceLock;
use tokio::io::{AsyncRead, AsyncReadExt};

const INITIAL_BUFFER_SIZE: usize = 262144; // 256KB
const DEFAULT_SHRINK_SIZE: usize = 8 * 1024 * 1024; // 8MB

static SHRINK_MESSAGE_SIZE: OnceLock<usize> = OnceLock::new();

/// Get the shrink message size threshold.
fn get_shrink_message_size() -> usize {
    *SHRINK_MESSAGE_SIZE.get_or_init(|| {
        let max_size = get_tcp_max_message_size();
        // Check for environment variable override
        let env_result = std::env::var("DYN_TCP_SHRINK_MESSAGE_SIZE");
        let env_shrink_size = env_result.as_ref().ok().and_then(|s| {
            s.parse::<usize>().ok().or_else(|| {
                tracing::warn!(
                    env_var = "DYN_TCP_SHRINK_MESSAGE_SIZE",
                    value = %s,
                    "Invalid value for DYN_TCP_SHRINK_MESSAGE_SIZE, using default"
                );
                None
            })
        });

        let resolved = resolve_shrink_message_size(max_size, env_shrink_size);

        // Warn if the configured value was clamped
        if let Some(configured) = env_shrink_size
            && configured != resolved
        {
            tracing::warn!(
                configured_size = configured,
                resolved_size = resolved,
                max_size = max_size,
                initial_buffer_size = INITIAL_BUFFER_SIZE,
                "DYN_TCP_SHRINK_MESSAGE_SIZE was clamped to valid range. Note the size is in bytes."
            );
        }

        resolved
    })
}

/// Resolve the shrink message size threshold based on configuration and constraints.
///
fn resolve_shrink_message_size(max_size: usize, env_shrink_size: Option<usize>) -> usize {
    let configured_size = env_shrink_size.unwrap_or(DEFAULT_SHRINK_SIZE);

    // Clamp to valid range: [INITIAL_BUFFER_SIZE, max_size]
    configured_size
        .min(max_size) // Don't exceed max message size
        .max(INITIAL_BUFFER_SIZE) // Don't go below initial buffer size
}

/// Zero-copy streaming decoder that reuses buffers
///
/// This decoder maintains an internal buffer and only allocates when necessary.
/// Messages are returned as Arc-counted Bytes slices, making cloning extremely cheap.
/// The reusable buffer resets back to INITIAL_BUFFER_SIZE only when unread data
/// is empty and capacity exceeds DYN_TCP_SHRINK_MESSAGE_SIZE.
pub struct ZeroCopyTcpDecoder {
    /// Reusable read buffer - grows as needed, shrinks when empty and oversized
    read_buffer: BytesMut,
    /// Maximum allowed message size
    max_message_size: usize,
    /// Threshold for shrinking buffer back to initial size when empty
    shrink_threshold: usize,
}

impl ZeroCopyTcpDecoder {
    /// Create a new decoder with default buffer size
    pub fn new() -> Self {
        Self::with_capacity(INITIAL_BUFFER_SIZE)
    }

    /// Create a new decoder with specific initial capacity
    pub fn with_capacity(capacity: usize) -> Self {
        Self {
            read_buffer: BytesMut::with_capacity(capacity),
            max_message_size: get_tcp_max_message_size(),
            shrink_threshold: get_shrink_message_size(),
        }
    }

    /// Read one complete message with ZERO copies
    ///
    /// This method:
    /// 1. Ensures headers are buffered
    /// 2. Parses headers in-place (no allocation)
    /// 3. Ensures entire message is buffered
    /// 4. Splits off exact message size (zero-copy pointer arithmetic)
    /// 5. Returns Arc-counted Bytes (cheap to clone)
    pub async fn read_message<R: AsyncRead + Unpin>(
        &mut self,
        reader: &mut R,
    ) -> io::Result<TcpRequestMessageZeroCopy> {
        // Fill buffer if needed
        while self.read_buffer.len() < super::TCP_REQUEST_ENDPOINT_LEN_WIDTH {
            let n = reader.read_buf(&mut self.read_buffer).await?;
            if n == 0 {
                if self.read_buffer.is_empty() {
                    return Err(io::Error::new(
                        io::ErrorKind::UnexpectedEof,
                        "connection closed",
                    ));
                } else {
                    return Err(io::Error::new(
                        io::ErrorKind::UnexpectedEof,
                        "incomplete message header",
                    ));
                }
            }
        }

        // Parse endpoint path length (first 2 bytes) - NO COPY
        let path_len = tcp_request_endpoint_len(&self.read_buffer)?;

        // Ensure we have path + headers_len
        let initial_header_size =
            super::TCP_REQUEST_ENDPOINT_LEN_WIDTH + path_len + super::TCP_REQUEST_HEADERS_LEN_WIDTH;
        while self.read_buffer.len() < initial_header_size {
            let n = reader.read_buf(&mut self.read_buffer).await?;
            if n == 0 {
                return Err(io::Error::new(
                    io::ErrorKind::UnexpectedEof,
                    "incomplete message header",
                ));
            }
        }

        // Parse headers length (2 bytes after path) - NO COPY
        let headers_len = tcp_request_headers_len(&self.read_buffer, path_len)?;

        // Ensure we have headers + payload length
        let full_header_size = tcp_request_header_size(path_len, headers_len);
        while self.read_buffer.len() < full_header_size {
            let n = reader.read_buf(&mut self.read_buffer).await?;
            if n == 0 {
                return Err(io::Error::new(
                    io::ErrorKind::UnexpectedEof,
                    "incomplete message header",
                ));
            }
        }

        let parsed = parse_tcp_request_frame_header(&self.read_buffer)?;

        // Sanity check total message length (including all overhead)
        check_tcp_request_max_message_size(parsed.total_len, self.max_message_size)?;

        // Ensure entire message is buffered
        while self.read_buffer.len() < parsed.total_len {
            let n = reader.read_buf(&mut self.read_buffer).await?;
            if n == 0 {
                return Err(io::Error::new(
                    io::ErrorKind::UnexpectedEof,
                    format!(
                        "incomplete message: expected {} bytes, got {}",
                        parsed.total_len,
                        self.read_buffer.len()
                    ),
                ));
            }
        }

        // Split off exactly what we need - ZERO COPY!
        // split_to() just advances the internal pointer, doesn't allocate or copy
        let message_bytes = self.read_buffer.split_to(parsed.total_len).freeze();

        // Shrink buffer if it grew too large and is now empty, could be optimized with lock-free buffer pool in the future.
        if self.read_buffer.is_empty() && self.read_buffer.capacity() > self.shrink_threshold {
            self.read_buffer = BytesMut::with_capacity(INITIAL_BUFFER_SIZE);
        }

        // Return zero-copy message wrapper
        Ok(TcpRequestMessageZeroCopy::new(message_bytes, parsed))
    }

    /// Get the current buffer capacity
    pub fn buffer_capacity(&self) -> usize {
        self.read_buffer.capacity()
    }

    /// Get the current buffered data size
    pub fn buffered_len(&self) -> usize {
        self.read_buffer.len()
    }
}

impl Default for ZeroCopyTcpDecoder {
    fn default() -> Self {
        Self::new()
    }
}

/// Zero-copy message representation
///
/// This struct holds an Arc-counted Bytes buffer containing the entire message.
/// All accessors return zero-copy slices or references into this buffer.
#[derive(Clone)]
pub struct TcpRequestMessageZeroCopy {
    /// Entire message as Arc-counted buffer
    /// Format: [path_len(2)][path(var)][headers_len(2)][headers(var)][payload_len(4)][payload(var)]
    raw: Bytes,
    parsed: super::TcpRequestWireHeader,
}

impl TcpRequestMessageZeroCopy {
    /// Create a new zero-copy message from raw bytes
    fn new(raw: Bytes, parsed: super::TcpRequestWireHeader) -> Self {
        Self { raw, parsed }
    }

    /// Get endpoint path as a string slice (zero-copy)
    ///
    /// This returns a reference into the message buffer, no allocation.
    pub fn endpoint_path(&self) -> Result<&str, std::str::Utf8Error> {
        std::str::from_utf8(&self.raw[self.parsed.endpoint_start()..self.parsed.endpoint_end()])
    }

    /// Get endpoint path as bytes (zero-copy)
    pub fn endpoint_path_bytes(&self) -> &[u8] {
        &self.raw[self.parsed.endpoint_start()..self.parsed.endpoint_end()]
    }

    /// Get headers as bytes (zero-copy)
    pub fn headers_bytes(&self) -> &[u8] {
        &self.raw[self.parsed.headers_start()..self.parsed.headers_end()]
    }

    /// Get headers as a HashMap (requires parsing)
    pub fn headers(&self) -> std::collections::HashMap<String, String> {
        let headers_bytes = self.headers_bytes();
        if headers_bytes.is_empty() {
            return std::collections::HashMap::new();
        }

        // Parse headers from JSON format
        serde_json::from_slice(headers_bytes).unwrap_or_default()
    }

    /// Get the payload length
    #[inline]
    fn payload_len(&self) -> usize {
        self.parsed.payload_len
    }

    /// Get payload as zero-copy Bytes
    ///
    /// This returns an Arc-counted slice of the message buffer.
    /// Cloning the returned Bytes is extremely cheap (just Arc clone).
    pub fn payload(&self) -> Bytes {
        self.raw.slice(self.parsed.payload_start()..) // ZERO COPY! Just Arc clone + offset
    }

    /// Get total message size in bytes
    pub fn total_size(&self) -> usize {
        self.raw.len()
    }

    /// Get the raw message bytes (for debugging)
    pub fn raw_bytes(&self) -> &Bytes {
        &self.raw
    }
}

impl std::fmt::Debug for TcpRequestMessageZeroCopy {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        f.debug_struct("TcpRequestMessageZeroCopy")
            .field("total_size", &self.total_size())
            .field("endpoint_path", &self.endpoint_path().ok())
            .field("payload_len", &self.payload_len())
            .finish()
    }
}

#[cfg(test)]
mod tests {
    use super::*;
    use tokio::io::AsyncWriteExt;

    #[test]
    fn test_resolve_shrink_message_size_edge_cases() {
        // Test case: max_size = 10MB (larger than DEFAULT_SHRINK_SIZE)
        // Should return DEFAULT_SHRINK_SIZE (8MB) since env is None
        let max_size_10mb = 10 * 1024 * 1024;
        let result = resolve_shrink_message_size(max_size_10mb, None);
        assert_eq!(
            result, DEFAULT_SHRINK_SIZE,
            "10MB max should return default 8MB"
        );

        // Test case: max_size < DEFAULT_SHRINK_SIZE
        // Should return max_size (capped by .min())
        let max_size_1mb = 1024 * 1024;
        let result = resolve_shrink_message_size(max_size_1mb, None);
        assert_eq!(result, max_size_1mb, "1MB max should be capped to 1MB");

        // Test case: max_size = DEFAULT_SHRINK_SIZE
        // Should return DEFAULT_SHRINK_SIZE (exact match)
        let result = resolve_shrink_message_size(DEFAULT_SHRINK_SIZE, None);
        assert_eq!(
            result, DEFAULT_SHRINK_SIZE,
            "exact match should return default"
        );

        // Test case: env_shrink_size provided and within bounds
        let env_size = 2 * 1024 * 1024; // 2MB
        let result = resolve_shrink_message_size(max_size_10mb, Some(env_size));
        assert_eq!(
            result, env_size,
            "env var should be used when within bounds"
        );

        // Test case: env_shrink_size exceeds max_size
        let env_size_large = 20 * 1024 * 1024; // 20MB
        let result = resolve_shrink_message_size(max_size_10mb, Some(env_size_large));
        assert_eq!(
            result, max_size_10mb,
            "env var should be capped to max_size"
        );

        // Test case: env_shrink_size below INITIAL_BUFFER_SIZE
        let env_size_small = 100 * 1024; // 100KB < 256KB
        let result = resolve_shrink_message_size(max_size_10mb, Some(env_size_small));
        assert_eq!(
            result, INITIAL_BUFFER_SIZE,
            "env var should be clamped to INITIAL_BUFFER_SIZE"
        );

        // Test case: max_size below INITIAL_BUFFER_SIZE
        let max_size_small = 100 * 1024; // 100KB < 256KB
        let result = resolve_shrink_message_size(max_size_small, None);
        assert_eq!(
            result, INITIAL_BUFFER_SIZE,
            "result should be clamped to INITIAL_BUFFER_SIZE"
        );
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_basic() {
        // Create a test message with headers
        let endpoint = "test/endpoint";
        let payload = b"Hello, World!";
        let headers: Vec<u8> = vec![]; // Empty headers

        let mut message = Vec::new();
        // path_len + path
        message.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
        message.extend_from_slice(endpoint.as_bytes());
        // headers_len + headers
        message.extend_from_slice(&(headers.len() as u16).to_be_bytes());
        message.extend_from_slice(&headers);
        // payload_len + payload
        message.extend_from_slice(&(payload.len() as u32).to_be_bytes());
        message.extend_from_slice(payload);

        // Create a mock reader
        let mut reader = &message[..];

        // Decode
        let mut decoder = ZeroCopyTcpDecoder::new();
        let msg = decoder.read_message(&mut reader).await.unwrap();

        // Verify
        assert_eq!(msg.endpoint_path().unwrap(), endpoint);
        assert_eq!(msg.payload().as_ref(), payload);
        assert_eq!(msg.total_size(), message.len());
        assert_eq!(msg.headers().len(), 0); // Empty headers
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_allows_empty_and_long_endpoint_paths() {
        for endpoint in [String::new(), "x".repeat(2048)] {
            let payload = b"payload";

            let mut message = Vec::new();
            message.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
            message.extend_from_slice(endpoint.as_bytes());
            message.extend_from_slice(&(0u16).to_be_bytes());
            message.extend_from_slice(&(payload.len() as u32).to_be_bytes());
            message.extend_from_slice(payload);

            let mut reader = &message[..];
            let mut decoder = ZeroCopyTcpDecoder::new();
            let msg = decoder.read_message(&mut reader).await.unwrap();

            assert_eq!(msg.endpoint_path().unwrap(), endpoint.as_str());
            assert_eq!(msg.payload().as_ref(), payload);
        }
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_large_payload() {
        // Create a large payload (200KB)
        let endpoint = "large/endpoint";
        let payload = vec![0x42u8; 200 * 1024];
        let headers: Vec<u8> = vec![]; // Empty headers

        let mut message = Vec::new();
        // path_len + path
        message.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
        message.extend_from_slice(endpoint.as_bytes());
        // headers_len + headers
        message.extend_from_slice(&(headers.len() as u16).to_be_bytes());
        message.extend_from_slice(&headers);
        // payload_len + payload
        message.extend_from_slice(&(payload.len() as u32).to_be_bytes());
        message.extend_from_slice(&payload);

        let mut reader = &message[..];
        let mut decoder = ZeroCopyTcpDecoder::new();
        let msg = decoder.read_message(&mut reader).await.unwrap();

        assert_eq!(msg.endpoint_path().unwrap(), endpoint);
        assert_eq!(msg.payload().len(), payload.len());
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_total_size_limit() {
        // Test that the decoder validates total message size, not just payload size
        // Create a message where total_len exceeds max but payload alone might not
        let max_size = 1024; // 1KB limit
        let mut decoder = ZeroCopyTcpDecoder::with_capacity(256);
        decoder.max_message_size = max_size;

        // Create a message that exceeds the limit with overhead included
        let endpoint = "test/endpoint";
        let payload = vec![0x42u8; max_size]; // Payload equals max
        let headers: Vec<u8> = vec![]; // Empty headers

        let mut message = Vec::new();
        // path_len + path
        message.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
        message.extend_from_slice(endpoint.as_bytes());
        // headers_len + headers
        message.extend_from_slice(&(headers.len() as u16).to_be_bytes());
        message.extend_from_slice(&headers);
        // payload_len + payload
        message.extend_from_slice(&(payload.len() as u32).to_be_bytes());
        message.extend_from_slice(&payload);

        // total_len = 2 + 13 + 2 + 0 + 4 + 1024 = 1045 bytes > 1024 max
        let mut reader = &message[..];
        let result = decoder.read_message(&mut reader).await;

        // Should fail with InvalidData error
        assert!(result.is_err());
        let err = result.unwrap_err();
        assert_eq!(err.kind(), io::ErrorKind::InvalidData);
        assert!(err.to_string().contains("message too large"));
        assert!(err.to_string().contains("1045")); // total_len
        assert!(err.to_string().contains("1024")); // max_message_size
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_with_headers() {
        // Test header parsing with actual header data
        let endpoint = "api/v1/inference";
        let payload = b"Request payload data";

        // Create mock headers as JSON
        let mut headers_map = std::collections::HashMap::new();
        headers_map.insert("traceparent".to_string(), "00-abc123-def456-01".to_string());
        headers_map.insert("user-agent".to_string(), "test-client/1.0".to_string());
        headers_map.insert("request-id".to_string(), "req-12345".to_string());

        let headers_json = serde_json::to_vec(&headers_map).unwrap();

        let mut message = Vec::new();
        // path_len + path
        message.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
        message.extend_from_slice(endpoint.as_bytes());
        // headers_len + headers (non-empty this time)
        message.extend_from_slice(&(headers_json.len() as u16).to_be_bytes());
        message.extend_from_slice(&headers_json);
        // payload_len + payload
        message.extend_from_slice(&(payload.len() as u32).to_be_bytes());
        message.extend_from_slice(payload);

        // Decode the message
        let mut reader = &message[..];
        let mut decoder = ZeroCopyTcpDecoder::new();
        let msg = decoder.read_message(&mut reader).await.unwrap();

        // Verify endpoint
        assert_eq!(msg.endpoint_path().unwrap(), endpoint);

        // Verify payload
        assert_eq!(msg.payload().as_ref(), payload);

        // Verify total size includes all components
        assert_eq!(msg.total_size(), message.len());

        // Verify headers are correctly parsed
        let decoded_headers = msg.headers();
        assert_eq!(decoded_headers.len(), 3);
        assert_eq!(
            decoded_headers.get("traceparent").unwrap(),
            "00-abc123-def456-01"
        );
        assert_eq!(
            decoded_headers.get("user-agent").unwrap(),
            "test-client/1.0"
        );
        assert_eq!(decoded_headers.get("request-id").unwrap(), "req-12345");

        // Verify headers_bytes returns the raw JSON
        let headers_bytes = msg.headers_bytes();
        assert_eq!(headers_bytes, &headers_json[..]);
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_empty_vs_populated_headers() {
        // Test both empty and populated headers in sequence to ensure proper parsing
        let endpoint = "test/endpoint";
        let payload = b"test data";

        // Test 1: Empty headers
        let mut message_empty = Vec::new();
        message_empty.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
        message_empty.extend_from_slice(endpoint.as_bytes());
        message_empty.extend_from_slice(&(0u16).to_be_bytes()); // headers_len = 0
        // No headers bytes
        message_empty.extend_from_slice(&(payload.len() as u32).to_be_bytes());
        message_empty.extend_from_slice(payload);

        let mut reader = &message_empty[..];
        let mut decoder = ZeroCopyTcpDecoder::new();
        let msg = decoder.read_message(&mut reader).await.unwrap();

        assert_eq!(msg.endpoint_path().unwrap(), endpoint);
        assert_eq!(msg.payload().as_ref(), payload);
        assert_eq!(msg.headers().len(), 0);
        assert_eq!(msg.headers_bytes().len(), 0);

        // Test 2: Populated headers with same decoder
        let mut headers_map = std::collections::HashMap::new();
        headers_map.insert("x-test-header".to_string(), "test-value".to_string());
        let headers_json = serde_json::to_vec(&headers_map).unwrap();

        let mut message_with_headers = Vec::new();
        message_with_headers.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
        message_with_headers.extend_from_slice(endpoint.as_bytes());
        message_with_headers.extend_from_slice(&(headers_json.len() as u16).to_be_bytes());
        message_with_headers.extend_from_slice(&headers_json);
        message_with_headers.extend_from_slice(&(payload.len() as u32).to_be_bytes());
        message_with_headers.extend_from_slice(payload);

        let mut reader = &message_with_headers[..];
        let msg = decoder.read_message(&mut reader).await.unwrap();

        assert_eq!(msg.endpoint_path().unwrap(), endpoint);
        assert_eq!(msg.payload().as_ref(), payload);
        assert_eq!(msg.headers().len(), 1);
        assert_eq!(msg.headers().get("x-test-header").unwrap(), "test-value");
    }

    #[tokio::test]
    async fn test_zero_copy_decoder_buffer_shrinking() {
        // Test that buffer shrinks back after reading a large message.
        // Uses small sizes to avoid env var dependencies and keep test fast.
        let endpoint = "test/endpoint";
        let small_payload = b"small";
        // Use 1MB payload with 512KB shrink threshold
        let large_payload = vec![0x42u8; 1024 * 1024]; // 1MB

        fn make_message(endpoint: &str, payload: &[u8]) -> Vec<u8> {
            let mut message = Vec::new();
            message.extend_from_slice(&(endpoint.len() as u16).to_be_bytes());
            message.extend_from_slice(endpoint.as_bytes());
            message.extend_from_slice(&(0u16).to_be_bytes()); // empty headers
            message.extend_from_slice(&(payload.len() as u32).to_be_bytes());
            message.extend_from_slice(payload);
            message
        }

        // Create decoder with explicit settings to avoid env var dependencies
        let mut decoder = ZeroCopyTcpDecoder::with_capacity(INITIAL_BUFFER_SIZE);
        decoder.max_message_size = 2 * 1024 * 1024; // 2MB max
        decoder.shrink_threshold = 512 * 1024; // 512KB shrink threshold

        assert!(decoder.buffer_capacity() <= INITIAL_BUFFER_SIZE);

        // Read large message - buffer grows during read, then shrinks after split_to()
        let large_message = make_message(endpoint, &large_payload);
        let mut reader = &large_message[..];
        decoder.read_message(&mut reader).await.unwrap();

        // After reading, buffer should have shrunk back because:
        // - The buffer grew to ~1MB to hold the message
        // - 1MB >= 512KB shrink threshold, so it triggers the shrink
        assert!(
            decoder.buffer_capacity() <= INITIAL_BUFFER_SIZE,
            "buffer should shrink after large message, got capacity {}",
            decoder.buffer_capacity()
        );
        assert!(
            decoder.buffered_len() == 0,
            "buffer should be empty after read"
        );

        // Read small message - should work fine with shrunk buffer
        let small_message = make_message(endpoint, small_payload);
        let mut reader = &small_message[..];
        let msg = decoder.read_message(&mut reader).await.unwrap();
        assert_eq!(msg.payload().as_ref(), small_payload);
    }
}