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use std::cmp; |
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#[derive(Debug, Eq, Hash, PartialEq)] |
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pub enum PerformanceClassifierResult { |
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ErrorTooShortInputVector, |
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ErrorDifferentInputVectorLengths, |
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Identical, |
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NewProgramIsAlwaysFaster, |
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NewProgramIsEqualOrFaster, |
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NewProgramIsAlwaysFasterWhenSkippingTheFirstSlice, |
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RejectNewProgram, |
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} |
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pub struct PerformanceClassifier { |
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number_of_items_in_first_slice: usize, |
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} |
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impl PerformanceClassifier { |
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pub fn new(number_of_items_in_first_slice: usize) -> Self { |
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assert!(number_of_items_in_first_slice > 0); |
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Self { |
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number_of_items_in_first_slice: number_of_items_in_first_slice |
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} |
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} |
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pub fn analyze(&self, steps0: &Vec<u64>, steps1: &Vec<u64>) -> PerformanceClassifierResult { |
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if steps0.len() != steps1.len() { |
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return PerformanceClassifierResult::ErrorDifferentInputVectorLengths; |
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} |
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let len = cmp::min(steps0.len(), steps1.len()); |
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if len <= self.number_of_items_in_first_slice { |
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return PerformanceClassifierResult::ErrorTooShortInputVector; |
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} |
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let first_slice0: &[u64] = &steps0[..self.number_of_items_in_first_slice]; |
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let first_slice1: &[u64] = &steps1[..self.number_of_items_in_first_slice]; |
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assert!(first_slice0.len() == self.number_of_items_in_first_slice); |
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assert!(first_slice1.len() == self.number_of_items_in_first_slice); |
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let last_slice0: &[u64] = &steps0[self.number_of_items_in_first_slice..]; |
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let last_slice1: &[u64] = &steps1[self.number_of_items_in_first_slice..]; |
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assert!(first_slice0.len() + last_slice0.len() == steps0.len()); |
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assert!(first_slice1.len() + last_slice1.len() == steps1.len()); |
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let (first_count_program0, first_count_same, first_count_program1) = Self::histogram(first_slice0, first_slice1); |
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let (last_count_program0, last_count_same, last_count_program1) = Self::histogram(last_slice0, last_slice1); |
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let count_program0 = first_count_program0 + last_count_program0; |
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let count_same = first_count_same + last_count_same; |
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let count_program1 = first_count_program1 + last_count_program1; |
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if count_program0 == 0 && count_same > 0 && count_program1 == 0 { |
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return PerformanceClassifierResult::Identical; |
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} |
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if count_program0 > 0 && count_same == 0 && count_program1 == 0 { |
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return PerformanceClassifierResult::NewProgramIsAlwaysFaster; |
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} |
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if count_program0 > 0 && count_same > 0 && count_program1 == 0 { |
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return PerformanceClassifierResult::NewProgramIsEqualOrFaster; |
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} |
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if first_count_program1 > 0 && |
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last_count_program0 > 0 && last_count_same == 0 && last_count_program1 == 0 { |
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return PerformanceClassifierResult::NewProgramIsAlwaysFasterWhenSkippingTheFirstSlice; |
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} |
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PerformanceClassifierResult::RejectNewProgram |
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} |
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fn histogram(steps0: &[u64], steps1: &[u64]) -> (usize, usize, usize) { |
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let mut count_same: usize = 0; |
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let mut count_less_than: usize = 0; |
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let mut count_greater_than: usize = 0; |
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let len = cmp::min(steps0.len(), steps1.len()); |
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for i in 0..len { |
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let steps0: u64 = steps0[i]; |
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let steps1: u64 = steps1[i]; |
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if steps0 < steps1 { |
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count_less_than += 1; |
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continue; |
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} |
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if steps0 > steps1 { |
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count_greater_than += 1; |
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continue; |
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} |
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count_same += 1; |
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} |
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(count_less_than, count_same, count_greater_than) |
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} |
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} |
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#[cfg(test)] |
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mod tests { |
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use super::*; |
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fn histogram(steps0: Vec<u64>, steps1: Vec<u64>) -> String { |
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let (a, b, c) = PerformanceClassifier::histogram(&steps0, &steps1); |
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format!("{} {} {}", a, b, c) |
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} |
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#[test] |
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fn test_10000_histogram() { |
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assert_eq!(histogram(vec![1, 1], vec![2, 2]), "2 0 0"); |
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assert_eq!(histogram(vec![1, 1], vec![1, 1]), "0 2 0"); |
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assert_eq!(histogram(vec![2, 2], vec![1, 1]), "0 0 2"); |
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assert_eq!(histogram(vec![1, 1, 2, 1], vec![2, 2, 2, 2]), "3 1 0"); |
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assert_eq!(histogram(vec![2, 2, 1, 2], vec![1, 1, 1, 1]), "0 1 3"); |
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assert_eq!(histogram(vec![5, 1, 5, 1], vec![2, 4, 2, 4]), "2 0 2"); |
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} |
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#[test] |
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fn test_20000_analyze_error_different_lengths() { |
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let steps0: Vec<u64> = vec![5, 5, 5, 5, 5]; |
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let steps1: Vec<u64> = vec![5, 5, 5, 5, 5, 666]; |
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let pc = PerformanceClassifier::new(2); |
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let result = pc.analyze(&steps0, &steps1); |
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assert_eq!(result, PerformanceClassifierResult::ErrorDifferentInputVectorLengths); |
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} |
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#[test] |
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fn test_20001_analyze_error_too_short() { |
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let steps: Vec<u64> = vec![5, 5, 5, 5, 5]; |
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let pc = PerformanceClassifier::new(10); |
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let result = pc.analyze(&steps, &steps); |
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assert_eq!(result, PerformanceClassifierResult::ErrorTooShortInputVector); |
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} |
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#[test] |
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fn test_30000_analyze_identical() { |
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let steps: Vec<u64> = vec![5, 5, 5, 5, 5]; |
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let pc = PerformanceClassifier::new(2); |
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let result = pc.analyze(&steps, &steps); |
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assert_eq!(result, PerformanceClassifierResult::Identical); |
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} |
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#[test] |
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fn test_30001_analyze_is_always_faster() { |
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let steps0: Vec<u64> = vec![4, 4, 3, 4, 2]; |
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let steps1: Vec<u64> = vec![5, 5, 5, 5, 5]; |
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let pc = PerformanceClassifier::new(3); |
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let result = pc.analyze(&steps0, &steps1); |
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assert_eq!(result, PerformanceClassifierResult::NewProgramIsAlwaysFaster); |
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} |
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#[test] |
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fn test_30002_analyze_new_program_is_equal_or_faster() { |
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let steps0: Vec<u64> = vec![4, 5, 3, 5, 2]; |
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let steps1: Vec<u64> = vec![5, 5, 5, 5, 5]; |
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let pc = PerformanceClassifier::new(3); |
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let result = pc.analyze(&steps0, &steps1); |
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assert_eq!(result, PerformanceClassifierResult::NewProgramIsEqualOrFaster); |
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} |
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#[test] |
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fn test_30003_analyze_new_program_is_equal_or_faster() { |
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let steps0: Vec<u64> = vec![40, 40, 40, 5, 5, 5]; |
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let steps1: Vec<u64> = vec![5, 5, 5, 40, 40, 40]; |
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let pc = PerformanceClassifier::new(3); |
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let result = pc.analyze(&steps0, &steps1); |
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assert_eq!(result, PerformanceClassifierResult::NewProgramIsAlwaysFasterWhenSkippingTheFirstSlice); |
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} |
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#[test] |
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fn test_40000_analyze_reject_new_program() { |
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let steps0: Vec<u64> = vec![40, 41, 43, 46, 50, 60]; |
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let steps1: Vec<u64> = vec![5, 5, 5, 5, 5, 5]; |
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let pc = PerformanceClassifier::new(3); |
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let result = pc.analyze(&steps0, &steps1); |
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assert_eq!(result, PerformanceClassifierResult::RejectNewProgram); |
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} |
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} |
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