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https://github.com/scottlamb/moonfire-nvr.git
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d8b8d5d5e0
The effect was that it'd allow any state for signal 0, when it should have allowed state 0 for any signal.
758 lines
28 KiB
Rust
758 lines
28 KiB
Rust
// This file is part of Moonfire NVR, a security camera network video recorder.
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// Copyright (C) 2019 Scott Lamb <slamb@slamb.org>
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//
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// In addition, as a special exception, the copyright holders give
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// permission to link the code of portions of this program with the
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// OpenSSL library under certain conditions as described in each
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// individual source file, and distribute linked combinations including
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// the two.
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//
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// You must obey the GNU General Public License in all respects for all
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// of the code used other than OpenSSL. If you modify file(s) with this
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// exception, you may extend this exception to your version of the
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// file(s), but you are not obligated to do so. If you do not wish to do
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// so, delete this exception statement from your version. If you delete
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// this exception statement from all source files in the program, then
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// also delete it here.
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//
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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use base::bail_t;
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use crate::coding;
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use crate::db::FromSqlUuid;
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use crate::recording;
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use failure::{Error, bail, format_err};
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use fnv::FnvHashMap;
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use rusqlite::{Connection, Transaction, params};
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use std::collections::{BTreeMap, BTreeSet};
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use std::collections::btree_map::Entry;
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use std::ops::Range;
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use uuid::Uuid;
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/// All state associated with signals. This is the entry point to this module.
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pub(crate) struct State {
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signals_by_id: BTreeMap<u32, Signal>,
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/// All types with known states. Note that currently there's no requirement an entry here
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/// exists for every `type_` specified in a `Signal`, and there's an implied `0` (unknown)
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/// state for every `Type`.
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types_by_uuid: FnvHashMap<Uuid, Type>,
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points_by_time: BTreeMap<recording::Time, Point>,
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/// `points_by_time` entries which need to be flushed to the database.
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dirty_by_time: BTreeSet<recording::Time>,
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}
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/// Representation of all signals at a point in time.
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/// Each point matches a `signal_change` table row (when flushed). However, the in-memory
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/// representation keeps not only the changes as of that time but also the complete prior state.
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#[derive(Default)]
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struct Point {
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/// All data associated with the point.
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///
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/// `data[0..changes_off]` represents previous state (immediately prior to this point).
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/// `data[changes_off..]` represents the changes at this point.
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///
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/// This representation could be 8 bytes shorter on 64-bit platforms by using a u32 for the
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/// lengths, but this would require some unsafe code.
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///
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/// The serialized form stored here must always be valid.
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data: Box<[u8]>,
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changes_off: usize,
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}
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impl Point {
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/// Creates a new point from `prev` and `changes`.
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///
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/// The caller is responsible for validation. In particular, `changes` must be a valid
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/// serialized form.
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fn new(prev: &BTreeMap<u32, u16>, changes: &[u8]) -> Self {
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let mut data = Vec::with_capacity(3 * prev.len() + changes.len());
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append_serialized(prev, &mut data);
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let changes_off = data.len();
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data.extend(changes);
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Point {
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data: data.into_boxed_slice(),
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changes_off,
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}
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}
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fn swap(&mut self, other: &mut Point) {
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std::mem::swap(&mut self.data, &mut other.data);
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std::mem::swap(&mut self.changes_off, &mut other.changes_off);
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}
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/// Returns an iterator over state as of immediately before this point.
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fn prev(&self) -> PointDataIterator {
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PointDataIterator::new(&self.data[0..self.changes_off])
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}
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/// Returns an iterator over changes in this point.
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fn changes(&self) -> PointDataIterator {
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PointDataIterator::new(&self.data[self.changes_off..])
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}
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/// Returns a mapping of signals to states immediately after this point.
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fn after(&self) -> BTreeMap<u32, u16> {
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let mut after = BTreeMap::new();
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let mut it = self.prev();
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while let Some((signal, state)) = it.next().expect("in-mem prev is valid") {
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after.insert(signal, state);
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}
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let mut it = self.changes();
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while let Some((signal, state)) = it.next().expect("in-mem changes is valid") {
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if state == 0 {
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after.remove(&signal);
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} else {
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after.insert(signal, state);
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}
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}
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after
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}
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}
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/// Appends a serialized form of `from` into `to`.
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///
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/// `from` must be an iterator of `(signal, state)` with signal numbers in monotonically increasing
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/// order.
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fn append_serialized<'a, I>(from: I, to: &mut Vec<u8>)
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where I: IntoIterator<Item = (&'a u32, &'a u16)> {
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let mut next_allowed = 0;
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for (&signal, &state) in from.into_iter() {
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assert!(signal >= next_allowed);
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coding::append_varint32(signal - next_allowed, to);
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coding::append_varint32(state as u32, to);
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next_allowed = signal + 1;
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}
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}
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fn serialize(from: &BTreeMap<u32, u16>) -> Vec<u8> {
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let mut to = Vec::with_capacity(3 * from.len());
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append_serialized(from, &mut to);
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to
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}
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struct PointDataIterator<'a> {
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data: &'a [u8],
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cur_pos: usize,
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cur_signal: u32,
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}
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impl<'a> PointDataIterator<'a> {
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fn new(data: &'a [u8]) -> Self {
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PointDataIterator {
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data,
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cur_pos: 0,
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cur_signal: 0,
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}
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}
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/// Returns an error, `None`, or `Some((signal, state))`.
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/// Note that errors should be impossible on in-memory data; this returns `Result` for
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/// validating blobs as they're read from the database.
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fn next(&mut self) -> Result<Option<(u32, u16)>, Error> {
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if self.cur_pos == self.data.len() {
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return Ok(None);
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}
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let (signal_delta, p) = coding::decode_varint32(self.data, self.cur_pos)
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.map_err(|()| format_err!("varint32 decode failure; data={:?} pos={}",
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self.data, self.cur_pos))?;
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let (state, p) = coding::decode_varint32(self.data, p)
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.map_err(|()| format_err!("varint32 decode failure; data={:?} pos={}",
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self.data, p))?;
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let signal = self.cur_signal.checked_add(signal_delta)
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.ok_or_else(|| format_err!("signal overflow: {} + {}",
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self.cur_signal, signal_delta))?;
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if state > u16::max_value() as u32 {
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bail!("state overflow: {}", state);
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}
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self.cur_pos = p;
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self.cur_signal = signal + 1;
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Ok(Some((signal, state as u16)))
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}
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fn to_map(mut self) -> Result<BTreeMap<u32, u16>, Error> {
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let mut out = BTreeMap::new();
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while let Some((signal, state)) = self.next()? {
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out.insert(signal, state);
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}
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Ok(out)
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}
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}
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/// Representation of a `signal_camera` row.
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/// `signal_id` is implied by the `Signal` which owns this struct.
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#[derive(Debug)]
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pub struct SignalCamera {
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pub camera_id: i32,
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pub type_: SignalCameraType,
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}
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/// Representation of the `type` field in a `signal_camera` row.
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#[derive(Debug)]
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pub enum SignalCameraType {
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Direct = 0,
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Indirect = 1,
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}
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#[derive(Copy, Clone, Debug, PartialEq, Eq)]
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pub struct ListStateChangesRow {
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pub when: recording::Time,
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pub signal: u32,
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pub state: u16,
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}
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impl State {
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pub fn init(conn: &Connection) -> Result<Self, Error> {
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let mut signals_by_id = State::init_signals(conn)?;
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State::fill_signal_cameras(conn, &mut signals_by_id)?;
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Ok(State {
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signals_by_id,
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types_by_uuid: State::init_types(conn)?,
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points_by_time: State::init_points(conn)?,
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dirty_by_time: BTreeSet::new(),
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})
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}
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pub fn list_changes_by_time(
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&self, desired_time: Range<recording::Time>, f: &mut dyn FnMut(&ListStateChangesRow)) {
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// First find the state immediately before. If it exists, include it.
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if let Some((&when, p)) = self.points_by_time.range(..desired_time.start).next_back() {
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for (&signal, &state) in &p.after() {
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f(&ListStateChangesRow {
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when,
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signal,
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state,
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});
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}
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}
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// Then include changes up to (but not including) the end time.
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for (&when, p) in self.points_by_time.range(desired_time.clone()) {
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let mut it = p.changes();
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while let Some((signal, state)) = it.next().expect("in-mem changes is valid") {
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f(&ListStateChangesRow {
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when,
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signal,
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state,
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});
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}
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}
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}
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pub fn update_signals(
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&mut self, when: Range<recording::Time>, signals: &[u32], states: &[u16])
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-> Result<(), base::Error> {
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// Do input validation before any mutation.
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self.update_signals_validate(signals, states)?;
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// Follow the std::ops::Range convention of considering a range empty if its start >= end.
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// Bailing early in the empty case isn't just an optimization; apply_observation_end would
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// be incorrect otherwise.
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if when.end <= when.start {
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return Ok(());
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}
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// Apply the end before the start so that the `prev` state can be examined.
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self.update_signals_end(when.end, signals, states);
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self.update_signals_start(when.start, signals, states);
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self.update_signals_middle(when, signals, states);
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Ok(())
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}
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/// Helper for `update_signals` to do validation.
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fn update_signals_validate(&self, signals: &[u32], states: &[u16]) -> Result<(), base::Error> {
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if signals.len() != states.len() {
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bail_t!(InvalidArgument, "signals and states must have same length");
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}
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let mut next_allowed = 0u32;
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for (&signal, &state) in signals.iter().zip(states) {
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if signal < next_allowed {
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bail_t!(InvalidArgument, "signals must be monotonically increasing");
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}
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match self.signals_by_id.get(&signal) {
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None => bail_t!(InvalidArgument, "unknown signal {}", signal),
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Some(ref s) => {
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let empty = Vec::new();
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let states = self.types_by_uuid.get(&s.type_)
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.map(|t| &t.states)
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.unwrap_or(&empty);
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if state != 0 && states.binary_search_by_key(&state, |s| s.value).is_err() {
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bail_t!(FailedPrecondition, "signal {} specifies unknown state {}",
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signal, state);
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}
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},
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}
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next_allowed = signal + 1;
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}
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Ok(())
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}
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/// Helper for `update_signals` to apply the end point.
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fn update_signals_end(&mut self, end: recording::Time, signals: &[u32], states: &[u16]) {
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let mut prev;
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let mut changes = BTreeMap::<u32, u16>::new();
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if let Some((&t, ref mut p)) = self.points_by_time.range_mut(..=end).next_back() {
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if t == end {
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// Already have a point at end. Adjust it. prev starts unchanged...
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prev = p.prev().to_map().expect("in-mem prev is valid");
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// ...and then prev and changes are altered to reflect the desired update.
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State::update_signals_end_maps(signals, states, &mut prev, &mut changes);
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// If this doesn't alter the new state, don't dirty the database.
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if changes.is_empty() {
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return;
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}
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// Any existing changes should still be applied. They win over reverting to prev.
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let mut it = p.changes();
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while let Some((signal, state)) = it.next().expect("in-mem changes is valid") {
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changes.entry(signal).and_modify(|e| *e = state).or_insert(state);
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}
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self.dirty_by_time.insert(t);
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p.swap(&mut Point::new(&prev, &serialize(&changes)));
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return;
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}
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// Don't have a point at end, but do have previous state.
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prev = p.after();
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} else {
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// No point at or before end. Start from scratch (all signals unknown).
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prev = BTreeMap::new();
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}
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// Create a new end point if necessary.
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State::update_signals_end_maps(signals, states, &mut prev, &mut changes);
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if changes.is_empty() {
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return;
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}
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self.dirty_by_time.insert(end);
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self.points_by_time.insert(end, Point::new(&prev, &serialize(&changes)));
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}
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/// Helper for `update_signals_end`. Adjusts `prev` (the state prior to the end point) to
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/// reflect the desired update (in `signals` and `states`). Adjusts `changes` (changes to
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/// execute at the end point) to undo the change.
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fn update_signals_end_maps(signals: &[u32], states: &[u16], prev: &mut BTreeMap<u32, u16>,
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changes: &mut BTreeMap<u32, u16>) {
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for (&signal, &state) in signals.iter().zip(states) {
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match prev.entry(signal) {
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Entry::Vacant(e) => {
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changes.insert(signal, 0);
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e.insert(state);
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},
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Entry::Occupied(mut e) => {
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if state == 0 {
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changes.insert(signal, *e.get());
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e.remove();
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} else if *e.get() != state {
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changes.insert(signal, *e.get());
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*e.get_mut() = state;
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}
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},
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}
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}
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}
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/// Helper for `update_signals` to apply the start point.
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fn update_signals_start(&mut self, start: recording::Time, signals: &[u32], states: &[u16]) {
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let prev;
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if let Some((&t, ref mut p)) = self.points_by_time.range_mut(..=start).next_back() {
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if t == start {
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// Reuse existing point at start.
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prev = p.prev().to_map().expect("in-mem prev is valid");
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let mut changes = p.changes().to_map().expect("in-mem changes is valid");
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let mut dirty = false;
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for (&signal, &state) in signals.iter().zip(states) {
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match changes.entry(signal) {
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Entry::Occupied(mut e) => {
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if *e.get() != state {
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dirty = true;
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if state == *prev.get(&signal).unwrap_or(&0) {
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e.remove();
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} else {
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*e.get_mut() = state;
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}
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}
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},
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Entry::Vacant(e) => {
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if signal != 0 {
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dirty = true;
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e.insert(state);
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}
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},
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}
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}
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if dirty {
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p.swap(&mut Point::new(&prev, &serialize(&changes)));
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self.dirty_by_time.insert(start);
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}
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return;
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}
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// Create new point at start, using state from previous point.
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prev = p.after();
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} else {
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// Create new point at start, from scratch.
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prev = BTreeMap::new();
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}
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let mut changes = BTreeMap::new();
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for (&signal, &state) in signals.iter().zip(states) {
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if state != *prev.get(&signal).unwrap_or(&0) {
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changes.insert(signal, state);
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}
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}
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if changes.is_empty() {
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return;
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}
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self.dirty_by_time.insert(start);
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self.points_by_time.insert(start, Point::new(&prev, &serialize(&changes)));
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}
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/// Helper for `update_signals` to apply all points in `(when.start, when.end)`.
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fn update_signals_middle(&mut self, when: Range<recording::Time>, signals: &[u32],
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states: &[u16]) {
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let mut to_delete = Vec::new();
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let after_start = recording::Time(when.start.0+1);
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for (&t, ref mut p) in self.points_by_time.range_mut(after_start..when.end) {
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let mut prev = p.prev().to_map().expect("in-mem prev is valid");
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// Update prev to reflect desired update.
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for (&signal, &state) in signals.iter().zip(states) {
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match prev.entry(signal) {
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Entry::Occupied(mut e) => {
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if state == 0 {
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e.remove_entry();
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} else if *e.get() != state {
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*e.get_mut() = state;
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}
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},
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Entry::Vacant(e) => {
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if state != 0 {
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e.insert(state);
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}
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}
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}
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}
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// Trim changes to omit any change to signals.
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let mut changes = Vec::with_capacity(3*signals.len());
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let mut it = p.changes();
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let mut next_allowed = 0;
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let mut dirty = false;
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while let Some((signal, state)) = it.next().expect("in-memory changes is valid") {
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if signals.binary_search(&signal).is_ok() { // discard.
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dirty = true;
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} else { // keep.
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assert!(signal >= next_allowed);
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coding::append_varint32(signal - next_allowed, &mut changes);
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coding::append_varint32(state as u32, &mut changes);
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next_allowed = signal + 1;
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}
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}
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if changes.is_empty() {
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to_delete.push(t);
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} else {
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p.swap(&mut Point::new(&prev, &changes));
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}
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if dirty {
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self.dirty_by_time.insert(t);
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}
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}
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// Delete any points with no more changes.
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|
for &t in &to_delete {
|
|
self.points_by_time.remove(&t).expect("point exists");
|
|
}
|
|
}
|
|
|
|
/// Flushes all pending database changes to the given transaction.
|
|
///
|
|
/// The caller is expected to call `post_flush` afterward if the transaction is
|
|
/// successfully committed. No mutations should happen between these calls.
|
|
pub fn flush(&mut self, tx: &Transaction) -> Result<(), Error> {
|
|
let mut i_stmt = tx.prepare(r#"
|
|
insert or replace into signal_change (time_90k, changes) values (?, ?)
|
|
"#)?;
|
|
let mut d_stmt = tx.prepare(r#"
|
|
delete from signal_change where time_90k = ?
|
|
"#)?;
|
|
for &t in &self.dirty_by_time {
|
|
match self.points_by_time.entry(t) {
|
|
Entry::Occupied(ref e) => {
|
|
let p = e.get();
|
|
i_stmt.execute(params![
|
|
t.0,
|
|
&p.data[p.changes_off..],
|
|
])?;
|
|
},
|
|
Entry::Vacant(_) => {
|
|
d_stmt.execute(&[t.0])?;
|
|
},
|
|
}
|
|
}
|
|
Ok(())
|
|
}
|
|
|
|
/// Marks that the previous `flush` was completed successfully.
|
|
///
|
|
/// See notes there.
|
|
pub fn post_flush(&mut self) {
|
|
self.dirty_by_time.clear();
|
|
}
|
|
|
|
fn init_signals(conn: &Connection) -> Result<BTreeMap<u32, Signal>, Error> {
|
|
let mut signals = BTreeMap::new();
|
|
let mut stmt = conn.prepare(r#"
|
|
select
|
|
id,
|
|
source_uuid,
|
|
type_uuid,
|
|
short_name
|
|
from
|
|
signal
|
|
"#)?;
|
|
let mut rows = stmt.query(params![])?;
|
|
while let Some(row) = rows.next()? {
|
|
let id = row.get(0)?;
|
|
let source: FromSqlUuid = row.get(1)?;
|
|
let type_: FromSqlUuid = row.get(2)?;
|
|
signals.insert(id, Signal {
|
|
id,
|
|
source: source.0,
|
|
type_: type_.0,
|
|
short_name: row.get(3)?,
|
|
cameras: Vec::new(),
|
|
});
|
|
}
|
|
Ok(signals)
|
|
}
|
|
|
|
fn init_points(conn: &Connection) -> Result<BTreeMap<recording::Time, Point>, Error> {
|
|
let mut stmt = conn.prepare(r#"
|
|
select
|
|
time_90k,
|
|
changes
|
|
from
|
|
signal_change
|
|
order by time_90k
|
|
"#)?;
|
|
let mut rows = stmt.query(params![])?;
|
|
let mut points = BTreeMap::new();
|
|
let mut cur = BTreeMap::new(); // latest signal -> state, where state != 0
|
|
while let Some(row) = rows.next()? {
|
|
let time_90k = recording::Time(row.get(0)?);
|
|
let changes = row.get_raw_checked(1)?.as_blob()?;
|
|
let mut it = PointDataIterator::new(changes);
|
|
while let Some((signal, state)) = it.next()? {
|
|
if state == 0 {
|
|
cur.remove(&signal);
|
|
} else {
|
|
cur.insert(signal, state);
|
|
}
|
|
}
|
|
points.insert(time_90k, Point::new(&cur, changes));
|
|
}
|
|
Ok(points)
|
|
}
|
|
|
|
/// Fills the `cameras` field of the `Signal` structs within the supplied `signals`.
|
|
fn fill_signal_cameras(conn: &Connection, signals: &mut BTreeMap<u32, Signal>)
|
|
-> Result<(), Error> {
|
|
let mut stmt = conn.prepare(r#"
|
|
select
|
|
signal_id,
|
|
camera_id,
|
|
type
|
|
from
|
|
signal_camera
|
|
order by signal_id, camera_id
|
|
"#)?;
|
|
let mut rows = stmt.query(params![])?;
|
|
while let Some(row) = rows.next()? {
|
|
let signal_id = row.get(0)?;
|
|
let s = signals.get_mut(&signal_id)
|
|
.ok_or_else(|| format_err!("signal_camera row for unknown signal id {}",
|
|
signal_id))?;
|
|
let type_ = row.get(2)?;
|
|
s.cameras.push(SignalCamera {
|
|
camera_id: row.get(1)?,
|
|
type_: match type_ {
|
|
0 => SignalCameraType::Direct,
|
|
1 => SignalCameraType::Indirect,
|
|
_ => bail!("unknown signal_camera type {}", type_),
|
|
},
|
|
});
|
|
}
|
|
Ok(())
|
|
}
|
|
|
|
fn init_types(conn: &Connection) -> Result<FnvHashMap<Uuid, Type>, Error> {
|
|
let mut types = FnvHashMap::default();
|
|
let mut stmt = conn.prepare(r#"
|
|
select
|
|
type_uuid,
|
|
value,
|
|
name,
|
|
motion,
|
|
color
|
|
from
|
|
signal_type_enum
|
|
order by type_uuid, value
|
|
"#)?;
|
|
let mut rows = stmt.query(params![])?;
|
|
while let Some(row) = rows.next()? {
|
|
let type_: FromSqlUuid = row.get(0)?;
|
|
types.entry(type_.0).or_insert_with(Type::default).states.push(TypeState {
|
|
value: row.get(1)?,
|
|
name: row.get(2)?,
|
|
motion: row.get(3)?,
|
|
color: row.get(4)?,
|
|
});
|
|
}
|
|
Ok(types)
|
|
}
|
|
|
|
pub fn signals_by_id(&self) -> &BTreeMap<u32, Signal> { &self.signals_by_id }
|
|
pub fn types_by_uuid(&self) -> &FnvHashMap<Uuid, Type> { & self.types_by_uuid }
|
|
}
|
|
|
|
/// Representation of a `signal` row.
|
|
#[derive(Debug)]
|
|
pub struct Signal {
|
|
pub id: u32,
|
|
pub source: Uuid,
|
|
pub type_: Uuid,
|
|
pub short_name: String,
|
|
|
|
/// The cameras this signal is associated with. Sorted by camera id, which is unique.
|
|
pub cameras: Vec<SignalCamera>,
|
|
}
|
|
|
|
/// Representation of a `signal_type_enum` row.
|
|
/// `type_uuid` is implied by the `Type` which owns this struct.
|
|
#[derive(Debug)]
|
|
pub struct TypeState {
|
|
pub value: u16,
|
|
pub name: String,
|
|
pub motion: bool,
|
|
pub color: String,
|
|
}
|
|
|
|
/// Representation of a signal type; currently this just gathers together the TypeStates.
|
|
#[derive(Debug, Default)]
|
|
pub struct Type {
|
|
/// The possible states associated with this type. They are sorted by value, which is unique.
|
|
pub states: Vec<TypeState>,
|
|
}
|
|
|
|
#[cfg(test)]
|
|
mod tests {
|
|
use crate::{db, testutil};
|
|
use rusqlite::Connection;
|
|
use super::*;
|
|
|
|
#[test]
|
|
fn test_point_data_it() {
|
|
// Example taken from the .sql file.
|
|
let data = b"\x01\x01\x01\x01\xc4\x01\x02";
|
|
let mut it = super::PointDataIterator::new(data);
|
|
assert_eq!(it.next().unwrap(), Some((1, 1)));
|
|
assert_eq!(it.next().unwrap(), Some((3, 1)));
|
|
assert_eq!(it.next().unwrap(), Some((200, 2)));
|
|
assert_eq!(it.next().unwrap(), None);
|
|
}
|
|
|
|
#[test]
|
|
fn test_empty_db() {
|
|
testutil::init();
|
|
let mut conn = Connection::open_in_memory().unwrap();
|
|
db::init(&mut conn).unwrap();
|
|
let s = State::init(&conn).unwrap();
|
|
s.list_changes_by_time(recording::Time::min_value() .. recording::Time::max_value(),
|
|
&mut |_r| panic!("no changes expected"));
|
|
}
|
|
|
|
#[test]
|
|
fn round_trip() {
|
|
testutil::init();
|
|
let mut conn = Connection::open_in_memory().unwrap();
|
|
db::init(&mut conn).unwrap();
|
|
conn.execute_batch(r#"
|
|
insert into signal (id, source_uuid, type_uuid, short_name)
|
|
values (1, x'1B3889C0A59F400DA24C94EBEB19CC3A',
|
|
x'EE66270FD9C648198B339720D4CBCA6B', 'a'),
|
|
(2, x'A4A73D9A53424EBCB9F6366F1E5617FA',
|
|
x'EE66270FD9C648198B339720D4CBCA6B', 'b');
|
|
|
|
insert into signal_type_enum (type_uuid, value, name, motion, color)
|
|
values (x'EE66270FD9C648198B339720D4CBCA6B', 1, 'still', 0, 'black'),
|
|
(x'EE66270FD9C648198B339720D4CBCA6B', 2, 'moving', 1, 'red');
|
|
"#).unwrap();
|
|
let mut s = State::init(&conn).unwrap();
|
|
s.list_changes_by_time(recording::Time::min_value() .. recording::Time::max_value(),
|
|
&mut |_r| panic!("no changes expected"));
|
|
const START: recording::Time = recording::Time(140067462600000); // 2019-04-26T11:59:00
|
|
const NOW: recording::Time = recording::Time(140067468000000); // 2019-04-26T12:00:00
|
|
s.update_signals(START..NOW, &[1, 2], &[2, 1]).unwrap();
|
|
let mut rows = Vec::new();
|
|
|
|
const EXPECTED: &[ListStateChangesRow] = &[
|
|
ListStateChangesRow {
|
|
when: START,
|
|
signal: 1,
|
|
state: 2,
|
|
},
|
|
ListStateChangesRow {
|
|
when: START,
|
|
signal: 2,
|
|
state: 1,
|
|
},
|
|
ListStateChangesRow {
|
|
when: NOW,
|
|
signal: 1,
|
|
state: 0,
|
|
},
|
|
ListStateChangesRow {
|
|
when: NOW,
|
|
signal: 2,
|
|
state: 0,
|
|
},
|
|
];
|
|
|
|
s.list_changes_by_time(recording::Time::min_value() .. recording::Time::max_value(),
|
|
&mut |r| rows.push(*r));
|
|
assert_eq!(&rows[..], EXPECTED);
|
|
|
|
{
|
|
let tx = conn.transaction().unwrap();
|
|
s.flush(&tx).unwrap();
|
|
tx.commit().unwrap();
|
|
}
|
|
|
|
drop(s);
|
|
let s = State::init(&conn).unwrap();
|
|
rows.clear();
|
|
s.list_changes_by_time(recording::Time::min_value() .. recording::Time::max_value(),
|
|
&mut |r| rows.push(*r));
|
|
assert_eq!(&rows[..], EXPECTED);
|
|
}
|
|
}
|