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use crate::chopper::chopper::{ChopperDriver, Source};
use crate::chopper::data_graph::{DataGraph, DataNode};
use crate::chopper::header_graph::{ChainId, HeaderGraph, NodeId, PinId};
use crate::chopper::types::{Header, Row, TimestampRange};
use crate::driver::source_row_buffer::SourceRowBuffer;
use crate::error::{CliResult, Error};
pub struct Driver {
sources: Vec<Box<dyn Source>>,
data_graph: DataGraph,
timestamp_range: TimestampRange,
}
impl Driver {
pub fn new(
sources: Vec<Box<dyn Source>>,
header_graph: HeaderGraph,
timestamp_range: TimestampRange,
headers: Vec<Header>,
) -> CliResult<Self> {
if sources.len() > header_graph.len() {
return Err(Error::from(
"Driver -- not enough header chains for sources. \
each source should have at least one header chain.",
));
}
let data_graph = header_graph.process_header(headers)?;
Ok(Driver {
sources,
data_graph,
timestamp_range,
})
}
fn drive(&mut self) -> CliResult<()> {
let mut row_buffers = self.get_row_buffers()?;
let mut buffer_len = row_buffers.len();
while buffer_len > 0 {
let buffer_index = Self::get_next_buffer_index(&row_buffers);
let next_row_buffer = &mut row_buffers[buffer_index];
let row = next_row_buffer.row().clone().unwrap();
let chain_id = next_row_buffer.chain_id();
Self::process_row(&mut self.data_graph, chain_id, 0, 0, row)?;
loop {
if !row_buffers[buffer_index].has_next(&self.timestamp_range)? {
self.flush(chain_id, 0)?;
row_buffers.remove(buffer_index);
}
break;
}
buffer_len = row_buffers.len();
}
Ok(())
}
fn get_row_buffers(&mut self) -> CliResult<Vec<SourceRowBuffer>> {
let mut row_buffers: Vec<SourceRowBuffer> = Vec::with_capacity(self.sources.len());
for i in 0..self.sources.len() {
let source = self.sources.pop().unwrap();
row_buffers.push(SourceRowBuffer::new(source, i, &self.timestamp_range)?);
}
Ok(row_buffers)
}
fn get_next_buffer_index(row_buffers: &Vec<SourceRowBuffer>) -> usize {
let min = row_buffers
.iter()
.enumerate()
.min_by(|&(_, i1), &(_, i2)| i1.timestamp().cmp(&i2.timestamp()))
.unwrap();
min.0
}
fn process_row(
data_graph: &mut DataGraph,
mut chain_id: ChainId,
mut node_id: NodeId,
mut pin_id: PinId,
mut row: Row,
) -> CliResult<()> {
let chain = data_graph.get_mut_chain(chain_id);
while node_id < chain.nodes().len() {
match chain.node(node_id) {
DataNode::DataSink(sink) => match sink.write_row_to_pin(pin_id, row)? {
Some(r) => {
row = r;
node_id += 1;
}
None => break,
},
DataNode::Merge(new_chain_id, new_pin_id) => {
chain_id = *new_chain_id;
node_id = 0;
pin_id = *new_pin_id;
Self::process_row(data_graph, chain_id, node_id, pin_id, row)?;
break;
}
DataNode::Split(chain_ids) => {
if pin_id < chain_ids.len() {
let new_chain_id = chain_ids[pin_id];
pin_id += 1;
Self::process_row(data_graph, new_chain_id, 0, pin_id, row.clone())?;
Self::process_row(data_graph, chain_id, 0, pin_id, row.clone())?;
}
break;
}
}
}
Ok(())
}
pub fn flush(&mut self, mut chain_id: ChainId, mut pin_id: PinId) -> CliResult<()> {
let mut node_id = 0;
let chain = self.data_graph.get_mut_chain(chain_id);
while chain.nodes().len() > node_id {
match chain.node(node_id) {
DataNode::DataSink(sink) => {
sink.flush()?;
node_id += 1
}
DataNode::Merge(new_chain_id, _pin_id) => {
chain_id = *new_chain_id;
self.flush(chain_id, 0)?;
break;
}
DataNode::Split(chain_ids) => {
if pin_id < chain_ids.len() {
let new_chain_id = chain_ids[pin_id];
pin_id += 1;
self.flush(new_chain_id, 0)?;
self.flush(chain_id, pin_id)?;
}
break;
}
}
}
Ok(())
}
}
impl ChopperDriver for Driver {
fn drive(&mut self) -> CliResult<()> {
self.drive()
}
}