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refactor: Move the difficulty tests into their own file

This commit is contained in:
teor 2020-08-03 17:47:32 +10:00 committed by Deirdre Connolly
parent c95d980bc2
commit 78b5bf5e9a
2 changed files with 283 additions and 276 deletions
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278
zebra-chain/src/block/difficulty.rs
View File

@ -17,10 +17,10 @@ use std::fmt;
use primitive_types::U256; use primitive_types::U256;
#[cfg(test)]
use proptest::prelude::*;
#[cfg(test)] #[cfg(test)]
use proptest_derive::Arbitrary; use proptest_derive::Arbitrary;
#[cfg(test)]
mod tests;
/// A 32-bit "compact bits" value, which represents the difficulty threshold for /// A 32-bit "compact bits" value, which represents the difficulty threshold for
/// a block header. /// a block header.
@ -243,277 +243,3 @@ impl PartialOrd<ExpandedDifficulty> for BlockHeaderHash {
} }
} }
} }
#[cfg(test)]
impl Arbitrary for ExpandedDifficulty {
type Parameters = ();
fn arbitrary_with(_args: ()) -> Self::Strategy {
(any::<[u8; 32]>())
.prop_map(|v| ExpandedDifficulty(U256::from_little_endian(&v)))
.boxed()
}
type Strategy = BoxedStrategy<Self>;
}
#[cfg(test)]
mod tests {
use super::*;
use color_eyre::eyre::Report;
use std::sync::Arc;
use crate::block::Block;
use crate::serialization::ZcashDeserialize;
// Alias the struct constants here, so the code is easier to read.
const PRECISION: u32 = CompactDifficulty::PRECISION;
const SIGN_BIT: u32 = CompactDifficulty::SIGN_BIT;
const UNSIGNED_MANTISSA_MASK: u32 = CompactDifficulty::UNSIGNED_MANTISSA_MASK;
const OFFSET: i32 = CompactDifficulty::OFFSET;
/// Test debug formatting.
#[test]
fn debug_format() {
zebra_test::init();
assert_eq!(
format!("{:?}", CompactDifficulty(0)),
"CompactDifficulty(0x00000000)"
);
assert_eq!(
format!("{:?}", CompactDifficulty(1)),
"CompactDifficulty(0x00000001)"
);
assert_eq!(
format!("{:?}", CompactDifficulty(u32::MAX)),
"CompactDifficulty(0xffffffff)"
);
assert_eq!(format!("{:?}", ExpandedDifficulty(U256::zero())), "ExpandedDifficulty(\"0000000000000000000000000000000000000000000000000000000000000000\")");
assert_eq!(format!("{:?}", ExpandedDifficulty(U256::one())), "ExpandedDifficulty(\"0100000000000000000000000000000000000000000000000000000000000000\")");
assert_eq!(format!("{:?}", ExpandedDifficulty(U256::MAX)), "ExpandedDifficulty(\"ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff\")");
}
/// Test zero values for CompactDifficulty.
#[test]
fn compact_zero() {
zebra_test::init();
let natural_zero = CompactDifficulty(0);
assert_eq!(natural_zero.to_expanded(), None);
// Small value zeroes
let small_zero_1 = CompactDifficulty(1);
assert_eq!(small_zero_1.to_expanded(), None);
let small_zero_max = CompactDifficulty(UNSIGNED_MANTISSA_MASK);
assert_eq!(small_zero_max.to_expanded(), None);
// Special-cased zeroes, negative in the floating-point representation
let sc_zero = CompactDifficulty(SIGN_BIT);
assert_eq!(sc_zero.to_expanded(), None);
let sc_zero_next = CompactDifficulty(SIGN_BIT + 1);
assert_eq!(sc_zero_next.to_expanded(), None);
let sc_zero_high = CompactDifficulty((1 << PRECISION) - 1);
assert_eq!(sc_zero_high.to_expanded(), None);
let sc_zero_max = CompactDifficulty(u32::MAX);
assert_eq!(sc_zero_max.to_expanded(), None);
}
/// Test extreme values for CompactDifficulty.
#[test]
fn compact_extremes() {
zebra_test::init();
// Values equal to one
let expanded_one = Some(ExpandedDifficulty(U256::one()));
let one = CompactDifficulty(OFFSET as u32 * (1 << PRECISION) + 1);
assert_eq!(one.to_expanded(), expanded_one);
let another_one = CompactDifficulty((1 << PRECISION) + (1 << 16));
assert_eq!(another_one.to_expanded(), expanded_one);
// Maximum mantissa
let expanded_mant = Some(ExpandedDifficulty(UNSIGNED_MANTISSA_MASK.into()));
let mant = CompactDifficulty(OFFSET as u32 * (1 << PRECISION) + UNSIGNED_MANTISSA_MASK);
assert_eq!(mant.to_expanded(), expanded_mant);
// Maximum valid exponent
let exponent: U256 = (31 * 8).into();
let expanded_exp = Some(ExpandedDifficulty(U256::from(2).pow(exponent)));
let exp = CompactDifficulty((31 + OFFSET as u32) * (1 << PRECISION) + 1);
assert_eq!(exp.to_expanded(), expanded_exp);
// Maximum valid mantissa and exponent
let exponent: U256 = (29 * 8).into();
let expanded_me = U256::from(UNSIGNED_MANTISSA_MASK) * U256::from(2).pow(exponent);
let expanded_me = Some(ExpandedDifficulty(expanded_me));
let me = CompactDifficulty((31 + 1) * (1 << PRECISION) + UNSIGNED_MANTISSA_MASK);
assert_eq!(me.to_expanded(), expanded_me);
// Maximum value, at least according to the spec
//
// According to ToTarget() in the spec, this value is
// `(2^23 - 1) * 256^253`, which is larger than the maximum expanded
// value. Therefore, a block can never pass with this threshold.
//
// zcashd rejects these blocks without comparing the hash.
let difficulty_max = CompactDifficulty(u32::MAX & !SIGN_BIT);
assert_eq!(difficulty_max.to_expanded(), None);
}
/// Test blocks using CompactDifficulty.
#[test]
#[spandoc::spandoc]
fn block_difficulty() -> Result<(), Report> {
zebra_test::init();
let mut blockchain = Vec::new();
for b in &[
&zebra_test::vectors::BLOCK_MAINNET_GENESIS_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_1_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_2_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_3_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_4_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_5_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_6_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_7_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_8_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_9_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_10_BYTES[..],
] {
let block = Arc::<Block>::zcash_deserialize(*b)?;
let hash: BlockHeaderHash = block.as_ref().into();
blockchain.push((block.clone(), block.coinbase_height().unwrap(), hash));
}
let zero = ExpandedDifficulty(U256::zero());
let one = ExpandedDifficulty(U256::one());
let max_value = ExpandedDifficulty(U256::MAX);
for (block, height, hash) in blockchain {
/// SPANDOC: Calculate the threshold for mainnet block {?height}
let threshold = block
.header
.difficulty_threshold
.to_expanded()
.expect("Chain blocks have valid difficulty thresholds.");
/// SPANDOC: Check the difficulty for mainnet block {?height, ?threshold, ?hash}
{
assert!(hash <= threshold);
// also check the comparison operators work
assert!(hash > zero);
assert!(hash > one);
assert!(hash < max_value);
}
}
Ok(())
}
/// Test ExpandedDifficulty ordering
#[test]
#[spandoc::spandoc]
#[allow(clippy::eq_op)]
fn expanded_order() -> Result<(), Report> {
zebra_test::init();
let zero = ExpandedDifficulty(U256::zero());
let one = ExpandedDifficulty(U256::one());
let max_value = ExpandedDifficulty(U256::MAX);
assert!(zero < one);
assert!(zero < max_value);
assert!(one < max_value);
assert_eq!(zero, zero);
assert!(zero <= one);
assert!(one >= zero);
assert!(one > zero);
Ok(())
}
/// Test ExpandedDifficulty and BlockHeaderHash ordering
#[test]
#[spandoc::spandoc]
fn expanded_hash_order() -> Result<(), Report> {
zebra_test::init();
let ex_zero = ExpandedDifficulty(U256::zero());
let ex_one = ExpandedDifficulty(U256::one());
let ex_max = ExpandedDifficulty(U256::MAX);
let hash_zero = BlockHeaderHash([0; 32]);
let hash_max = BlockHeaderHash([0xff; 32]);
assert_eq!(hash_zero, ex_zero);
assert!(hash_zero < ex_one);
assert!(hash_zero < ex_max);
assert!(hash_max > ex_zero);
assert!(hash_max > ex_one);
assert_eq!(hash_max, ex_max);
assert!(ex_one > hash_zero);
assert!(ex_one < hash_max);
assert!(hash_zero >= ex_zero);
assert!(ex_zero >= hash_zero);
assert!(hash_zero <= ex_zero);
assert!(ex_zero <= hash_zero);
Ok(())
}
proptest! {
/// Check that CompactDifficulty expands without panicking, and compares
/// correctly.
#[test]
fn prop_compact_expand(compact in any::<CompactDifficulty>()) {
// TODO: round-trip test, once we have ExpandedDifficulty::to_compact()
let expanded = compact.to_expanded();
let hash_zero = BlockHeaderHash([0; 32]);
let hash_max = BlockHeaderHash([0xff; 32]);
if let Some(expanded) = expanded {
prop_assert!(expanded >= hash_zero);
prop_assert!(expanded <= hash_max);
}
}
/// Check that a random ExpandedDifficulty compares correctly with fixed BlockHeaderHashes.
#[test]
fn prop_expanded_order(expanded in any::<ExpandedDifficulty>()) {
// TODO: round-trip test, once we have ExpandedDifficulty::to_compact()
let hash_zero = BlockHeaderHash([0; 32]);
let hash_max = BlockHeaderHash([0xff; 32]);
prop_assert!(expanded >= hash_zero);
prop_assert!(expanded <= hash_max);
}
/// Check that ExpandedDifficulty compares correctly with a random BlockHeaderHash.
#[test]
fn prop_hash_order(hash in any::<BlockHeaderHash>()) {
let ex_zero = ExpandedDifficulty(U256::zero());
let ex_one = ExpandedDifficulty(U256::one());
let ex_max = ExpandedDifficulty(U256::MAX);
prop_assert!(hash >= ex_zero);
prop_assert!(hash <= ex_max);
prop_assert!(hash >= ex_one || hash == ex_zero);
}
/// Check that a random ExpandedDifficulty and BlockHeaderHash compare correctly.
#[test]
#[allow(clippy::double_comparisons)]
fn prop_expanded_hash_order(expanded in any::<ExpandedDifficulty>(), hash in any::<BlockHeaderHash>()) {
prop_assert!(expanded < hash || expanded > hash || expanded == hash);
}
}
}

281
zebra-chain/src/block/difficulty/tests.rs Normal file
View File

@ -0,0 +1,281 @@
//! Tests for difficulty and work
use super::*;
use crate::block::Block;
use crate::serialization::ZcashDeserialize;
use color_eyre::eyre::Report;
use proptest::prelude::*;
use std::sync::Arc;
// Alias the struct constants here, so the code is easier to read.
const PRECISION: u32 = CompactDifficulty::PRECISION;
const SIGN_BIT: u32 = CompactDifficulty::SIGN_BIT;
const UNSIGNED_MANTISSA_MASK: u32 = CompactDifficulty::UNSIGNED_MANTISSA_MASK;
const OFFSET: i32 = CompactDifficulty::OFFSET;
impl Arbitrary for ExpandedDifficulty {
type Parameters = ();
fn arbitrary_with(_args: ()) -> Self::Strategy {
(any::<[u8; 32]>())
.prop_map(|v| ExpandedDifficulty(U256::from_little_endian(&v)))
.boxed()
}
type Strategy = BoxedStrategy<Self>;
}
/// Test debug formatting.
#[test]
fn debug_format() {
zebra_test::init();
assert_eq!(
format!("{:?}", CompactDifficulty(0)),
"CompactDifficulty(0x00000000)"
);
assert_eq!(
format!("{:?}", CompactDifficulty(1)),
"CompactDifficulty(0x00000001)"
);
assert_eq!(
format!("{:?}", CompactDifficulty(u32::MAX)),
"CompactDifficulty(0xffffffff)"
);
assert_eq!(
format!("{:?}", ExpandedDifficulty(U256::zero())),
"ExpandedDifficulty(\"0000000000000000000000000000000000000000000000000000000000000000\")"
);
assert_eq!(
format!("{:?}", ExpandedDifficulty(U256::one())),
"ExpandedDifficulty(\"0100000000000000000000000000000000000000000000000000000000000000\")"
);
assert_eq!(
format!("{:?}", ExpandedDifficulty(U256::MAX)),
"ExpandedDifficulty(\"ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff\")"
);
}
/// Test zero values for CompactDifficulty.
#[test]
fn compact_zero() {
zebra_test::init();
let natural_zero = CompactDifficulty(0);
assert_eq!(natural_zero.to_expanded(), None);
// Small value zeroes
let small_zero_1 = CompactDifficulty(1);
assert_eq!(small_zero_1.to_expanded(), None);
let small_zero_max = CompactDifficulty(UNSIGNED_MANTISSA_MASK);
assert_eq!(small_zero_max.to_expanded(), None);
// Special-cased zeroes, negative in the floating-point representation
let sc_zero = CompactDifficulty(SIGN_BIT);
assert_eq!(sc_zero.to_expanded(), None);
let sc_zero_next = CompactDifficulty(SIGN_BIT + 1);
assert_eq!(sc_zero_next.to_expanded(), None);
let sc_zero_high = CompactDifficulty((1 << PRECISION) - 1);
assert_eq!(sc_zero_high.to_expanded(), None);
let sc_zero_max = CompactDifficulty(u32::MAX);
assert_eq!(sc_zero_max.to_expanded(), None);
}
/// Test extreme values for CompactDifficulty.
#[test]
fn compact_extremes() {
zebra_test::init();
// Values equal to one
let expanded_one = Some(ExpandedDifficulty(U256::one()));
let one = CompactDifficulty(OFFSET as u32 * (1 << PRECISION) + 1);
assert_eq!(one.to_expanded(), expanded_one);
let another_one = CompactDifficulty((1 << PRECISION) + (1 << 16));
assert_eq!(another_one.to_expanded(), expanded_one);
// Maximum mantissa
let expanded_mant = Some(ExpandedDifficulty(UNSIGNED_MANTISSA_MASK.into()));
let mant = CompactDifficulty(OFFSET as u32 * (1 << PRECISION) + UNSIGNED_MANTISSA_MASK);
assert_eq!(mant.to_expanded(), expanded_mant);
// Maximum valid exponent
let exponent: U256 = (31 * 8).into();
let expanded_exp = Some(ExpandedDifficulty(U256::from(2).pow(exponent)));
let exp = CompactDifficulty((31 + OFFSET as u32) * (1 << PRECISION) + 1);
assert_eq!(exp.to_expanded(), expanded_exp);
// Maximum valid mantissa and exponent
let exponent: U256 = (29 * 8).into();
let expanded_me = U256::from(UNSIGNED_MANTISSA_MASK) * U256::from(2).pow(exponent);
let expanded_me = Some(ExpandedDifficulty(expanded_me));
let me = CompactDifficulty((31 + 1) * (1 << PRECISION) + UNSIGNED_MANTISSA_MASK);
assert_eq!(me.to_expanded(), expanded_me);
// Maximum value, at least according to the spec
//
// According to ToTarget() in the spec, this value is
// `(2^23 - 1) * 256^253`, which is larger than the maximum expanded
// value. Therefore, a block can never pass with this threshold.
//
// zcashd rejects these blocks without comparing the hash.
let difficulty_max = CompactDifficulty(u32::MAX & !SIGN_BIT);
assert_eq!(difficulty_max.to_expanded(), None);
}
/// Test blocks using CompactDifficulty.
#[test]
#[spandoc::spandoc]
fn block_difficulty() -> Result<(), Report> {
zebra_test::init();
let mut blockchain = Vec::new();
for b in &[
&zebra_test::vectors::BLOCK_MAINNET_GENESIS_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_1_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_2_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_3_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_4_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_5_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_6_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_7_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_8_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_9_BYTES[..],
&zebra_test::vectors::BLOCK_MAINNET_10_BYTES[..],
] {
let block = Arc::<Block>::zcash_deserialize(*b)?;
let hash: BlockHeaderHash = block.as_ref().into();
blockchain.push((block.clone(), block.coinbase_height().unwrap(), hash));
}
let zero = ExpandedDifficulty(U256::zero());
let one = ExpandedDifficulty(U256::one());
let max_value = ExpandedDifficulty(U256::MAX);
for (block, height, hash) in blockchain {
/// SPANDOC: Calculate the threshold for mainnet block {?height}
let threshold = block
.header
.difficulty_threshold
.to_expanded()
.expect("Chain blocks have valid difficulty thresholds.");
/// SPANDOC: Check the difficulty for mainnet block {?height, ?threshold, ?hash}
{
assert!(hash <= threshold);
// also check the comparison operators work
assert!(hash > zero);
assert!(hash > one);
assert!(hash < max_value);
}
}
Ok(())
}
/// Test ExpandedDifficulty ordering
#[test]
#[spandoc::spandoc]
#[allow(clippy::eq_op)]
fn expanded_order() -> Result<(), Report> {
zebra_test::init();
let zero = ExpandedDifficulty(U256::zero());
let one = ExpandedDifficulty(U256::one());
let max_value = ExpandedDifficulty(U256::MAX);
assert!(zero < one);
assert!(zero < max_value);
assert!(one < max_value);
assert_eq!(zero, zero);
assert!(zero <= one);
assert!(one >= zero);
assert!(one > zero);
Ok(())
}
/// Test ExpandedDifficulty and BlockHeaderHash ordering
#[test]
#[spandoc::spandoc]
fn expanded_hash_order() -> Result<(), Report> {
zebra_test::init();
let ex_zero = ExpandedDifficulty(U256::zero());
let ex_one = ExpandedDifficulty(U256::one());
let ex_max = ExpandedDifficulty(U256::MAX);
let hash_zero = BlockHeaderHash([0; 32]);
let hash_max = BlockHeaderHash([0xff; 32]);
assert_eq!(hash_zero, ex_zero);
assert!(hash_zero < ex_one);
assert!(hash_zero < ex_max);
assert!(hash_max > ex_zero);
assert!(hash_max > ex_one);
assert_eq!(hash_max, ex_max);
assert!(ex_one > hash_zero);
assert!(ex_one < hash_max);
assert!(hash_zero >= ex_zero);
assert!(ex_zero >= hash_zero);
assert!(hash_zero <= ex_zero);
assert!(ex_zero <= hash_zero);
Ok(())
}
proptest! {
/// Check that CompactDifficulty expands without panicking, and compares
/// correctly.
#[test]
fn prop_compact_expand(compact in any::<CompactDifficulty>()) {
// TODO: round-trip test, once we have ExpandedDifficulty::to_compact()
let expanded = compact.to_expanded();
let hash_zero = BlockHeaderHash([0; 32]);
let hash_max = BlockHeaderHash([0xff; 32]);
if let Some(expanded) = expanded {
prop_assert!(expanded >= hash_zero);
prop_assert!(expanded <= hash_max);
}
}
/// Check that a random ExpandedDifficulty compares correctly with fixed BlockHeaderHashes.
#[test]
fn prop_expanded_order(expanded in any::<ExpandedDifficulty>()) {
// TODO: round-trip test, once we have ExpandedDifficulty::to_compact()
let hash_zero = BlockHeaderHash([0; 32]);
let hash_max = BlockHeaderHash([0xff; 32]);
prop_assert!(expanded >= hash_zero);
prop_assert!(expanded <= hash_max);
}
/// Check that ExpandedDifficulty compares correctly with a random BlockHeaderHash.
#[test]
fn prop_hash_order(hash in any::<BlockHeaderHash>()) {
let ex_zero = ExpandedDifficulty(U256::zero());
let ex_one = ExpandedDifficulty(U256::one());
let ex_max = ExpandedDifficulty(U256::MAX);
prop_assert!(hash >= ex_zero);
prop_assert!(hash <= ex_max);
prop_assert!(hash >= ex_one || hash == ex_zero);
}
/// Check that a random ExpandedDifficulty and BlockHeaderHash compare correctly.
#[test]
#[allow(clippy::double_comparisons)]
fn prop_expanded_hash_order(expanded in any::<ExpandedDifficulty>(), hash in any::<BlockHeaderHash>()) {
prop_assert!(expanded < hash || expanded > hash || expanded == hash);
}
}