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structured.rs
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structured.rs
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//! This example demonstrates how to work with structured
//! keys and values without paying expensive (de)serialization
//! costs.
//!
//! The `upsert` function shows how to use structured keys and values.
//!
//! The `variable_lengths` function shows how to put a variable length
//! component in either the beginning or the end of your value.
//!
//! The `hash_join` function shows how to do some SQL-like joins.
//!
//! Running this example several times via `cargo run --example structured`
//! will initialize the count field to 0, and on subsequent runs it will
//! increment it.
use {
byteorder::{BigEndian, LittleEndian},
zerocopy::{
byteorder::U64, AsBytes, FromBytes, LayoutVerified, Unaligned, U16, U32,
},
};
fn upsert(db: &sled::Db) -> sled::Result<()> {
// We use `BigEndian` for key types because
// they preserve lexicographic ordering,
// which is nice if we ever want to iterate
// over our items in order. We use the
// `U64` type from zerocopy because it
// does not have alignment requirements.
// sled does not guarantee any particular
// value alignment as of now.
#[derive(FromBytes, AsBytes, Unaligned)]
#[repr(C)]
struct Key {
a: U64<BigEndian>,
b: U64<BigEndian>,
}
// We use `LittleEndian` for values because
// it's possibly cheaper, but the difference
// isn't likely to be measurable, so honestly
// use whatever you want for values.
#[derive(FromBytes, AsBytes, Unaligned)]
#[repr(C)]
struct Value {
count: U64<LittleEndian>,
whatever: [u8; 16],
}
let key = Key { a: U64::new(21), b: U64::new(890) };
// "UPSERT" functionality
db.update_and_fetch(key.as_bytes(), |value_opt| {
if let Some(existing) = value_opt {
// We need to make a copy that will be written back
// into the database. This allows other threads that
// may have witnessed the old version to keep working
// without taking out any locks. IVec will be
// stack-allocated until it reaches 22 bytes
let mut backing_bytes = sled::IVec::from(existing);
// this verifies that our value is the correct length
// and alignment (in this case we don't need it to be
// aligned, because we use the `U64` type from zerocopy)
let layout: LayoutVerified<&mut [u8], Value> =
LayoutVerified::new_unaligned(&mut *backing_bytes)
.expect("bytes do not fit schema");
// this lets us work with the underlying bytes as
// a mutable structured value.
let value: &mut Value = layout.into_mut();
let new_count = value.count.get() + 1;
println!("incrementing count to {}", new_count);
value.count.set(new_count);
Some(backing_bytes)
} else {
println!("setting count to 0");
Some(sled::IVec::from(
Value { count: U64::new(0), whatever: [0; 16] }.as_bytes(),
))
}
})?;
Ok(())
}
// Cat values will be:
// favorite_number + battles_won + <home name variable bytes>
#[derive(FromBytes, AsBytes, Unaligned)]
#[repr(C)]
struct CatValue {
favorite_number: U64<LittleEndian>,
battles_won: U64<LittleEndian>,
}
// Dog values will be:
// <home name variable bytes> + woof_count + postal_code
#[derive(FromBytes, AsBytes, Unaligned)]
#[repr(C)]
struct DogValue {
woof_count: U32<LittleEndian>,
postal_code: U16<LittleEndian>,
}
fn variable_lengths(db: &sled::Db) -> sled::Result<()> {
// here we will show how we can use zerocopy for inserting
// fixed-size components, mixed with variable length
// records on the end or beginning.
// the hash_join example below shows how to read items
// out in a way that accounts for the variable portion,
// using `zerocopy::LayoutVerified::{new_from_prefix, new_from_suffix}`
let dogs = db.open_tree(b"dogs")?;
let mut dog2000_value = vec![];
dog2000_value.extend_from_slice(b"science zone");
dog2000_value.extend_from_slice(
DogValue { woof_count: U32::new(666), postal_code: U16::new(42) }
.as_bytes(),
);
dogs.insert("dog2000", dog2000_value)?;
let mut zed_pup_value = vec![];
zed_pup_value.extend_from_slice(b"bowling alley");
zed_pup_value.extend_from_slice(
DogValue { woof_count: U32::new(32113231), postal_code: U16::new(0) }
.as_bytes(),
);
dogs.insert("zed pup", zed_pup_value)?;
// IMPORTANT NOTE: German dogs eat food called "barf"
let mut klaus_value = vec![];
klaus_value.extend_from_slice(b"barf shop");
klaus_value.extend_from_slice(
DogValue { woof_count: U32::new(0), postal_code: U16::new(12045) }
.as_bytes(),
);
dogs.insert("klaus", klaus_value)?;
let cats = db.open_tree(b"cats")?;
let mut laser_cat_value = vec![];
laser_cat_value.extend_from_slice(
CatValue {
favorite_number: U64::new(11),
battles_won: U64::new(321231321),
}
.as_bytes(),
);
laser_cat_value.extend_from_slice(b"science zone");
cats.insert("laser cat", laser_cat_value)?;
let mut pulsar_cat_value = vec![];
pulsar_cat_value.extend_from_slice(
CatValue {
favorite_number: U64::new(11),
battles_won: U64::new(321231321),
}
.as_bytes(),
);
pulsar_cat_value.extend_from_slice(b"science zone");
cats.insert("pulsar cat", pulsar_cat_value)?;
let mut fluffy_value = vec![];
fluffy_value.extend_from_slice(
CatValue {
favorite_number: U64::new(11),
battles_won: U64::new(321231321),
}
.as_bytes(),
);
fluffy_value.extend_from_slice(b"bowling alley");
cats.insert("fluffy", fluffy_value)?;
Ok(())
}
fn hash_join(db: &sled::Db) -> sled::Result<()> {
// here we will try to find cats and dogs who
// live in the same home.
let cats = db.open_tree(b"cats")?;
let dogs = db.open_tree(b"dogs")?;
let mut join = std::collections::HashMap::new();
for name_value_res in &cats {
// cats are stored as name -> favorite_number + battles_won + home name
// variable bytes
let (name, value_bytes) = name_value_res?;
let (_, home_name): (LayoutVerified<&[u8], CatValue>, &[u8]) =
LayoutVerified::new_from_prefix(&*value_bytes).unwrap();
let (ref mut cat_names, _dog_names) =
join.entry(home_name.to_vec()).or_insert((vec![], vec![]));
cat_names.push(std::str::from_utf8(&*name).unwrap().to_string());
}
for name_value_res in &dogs {
// dogs are stored as name -> home name variable bytes + woof count +
// postal code
let (name, value_bytes) = name_value_res?;
// note that this is reversed from the cat example above, where
// the variable bytes are at the other end of the value, and are
// extracted using new_from_prefix instead of new_from_suffix.
let (home_name, _dog_value): (_, LayoutVerified<&[u8], DogValue>) =
LayoutVerified::new_from_suffix(&*value_bytes).unwrap();
if let Some((_cat_names, ref mut dog_names)) = join.get_mut(home_name) {
dog_names.push(std::str::from_utf8(&*name).unwrap().to_string());
}
}
for (home, (cats, dogs)) in join {
println!(
"the cats {:?} and the dogs {:?} live in the same home of {}",
cats,
dogs,
std::str::from_utf8(&home).unwrap()
);
}
Ok(())
}
fn main() -> sled::Result<()> {
let db = sled::open("my_database")?;
upsert(&db)?;
variable_lengths(&db)?;
hash_join(&db)?;
Ok(())
}