Letta MCP Server

#![cfg(feature = "power-of-two")] use lexical_parse_float::binary::{binary, slow_binary}; use lexical_parse_float::number::Number; use lexical_util::format::NumberFormatBuilder; const BINARY: u128 = NumberFormatBuilder::from_radix(2); const BASE4: u128 = NumberFormatBuilder::from_radix(4); const OCTAL: u128 = NumberFormatBuilder::from_radix(8); const HEX: u128 = NumberFormatBuilder::from_radix(16); const BASE32: u128 = NumberFormatBuilder::from_radix(32); fn compute_float32<const FORMAT: u128>(q: i64, w: u64, many_digits: bool) -> (i32, u64) { let num = Number { exponent: q, mantissa: w, is_negative: false, many_digits, integer: &[], fraction: None, }; let fp = binary::<f32, FORMAT>(&num, false); (fp.exp, fp.mant) } fn compute_float64<const FORMAT: u128>(q: i64, w: u64, many_digits: bool) -> (i32, u64) { let num = Number { exponent: q, mantissa: w, is_negative: false, many_digits, integer: &[], fraction: None, }; let fp = binary::<f64, FORMAT>(&num, false); (fp.exp, fp.mant) } #[test] fn computef32_test() { // Halfway, round-down tests assert_eq!(compute_float32::<BINARY>(0, 16777216, false), (151, 0)); assert_eq!(compute_float32::<BINARY>(0, 16777217, false), (151, 0)); assert_eq!(compute_float32::<BINARY>(0, 16777218, false), (151, 1)); assert_eq!(compute_float32::<BINARY>(0, 33554432, false), (152, 0)); assert_eq!(compute_float32::<BINARY>(0, 33554434, false), (152, 0)); assert_eq!(compute_float32::<BINARY>(0, 33554436, false), (152, 1)); } #[test] fn halfway_round_down_test() { // Halfway, round-down tests assert_eq!(compute_float64::<BINARY>(0, 9007199254740992, false), (1076, 0)); assert_eq!(compute_float64::<BINARY>(0, 9007199254740993, false), (1076, 0)); assert_eq!(compute_float64::<BINARY>(0, 9007199254740994, false), (1076, 1)); assert_eq!(compute_float64::<BINARY>(0, 18014398509481984, false), (1077, 0)); assert_eq!(compute_float64::<BINARY>(0, 18014398509481986, false), (1077, 0)); assert_eq!(compute_float64::<BINARY>(0, 18014398509481988, false), (1077, 1)); assert_eq!(compute_float64::<BINARY>(0, 9223372036854775808, false), (1086, 0)); assert_eq!(compute_float64::<BINARY>(0, 9223372036854776832, false), (1086, 0)); assert_eq!(compute_float64::<BINARY>(0, 9223372036854777856, false), (1086, 1)); // Add a 0 but say we're truncated. assert_eq!(compute_float64::<BINARY>(-10, 9223372036854775808, true), (1076, 0)); assert_eq!( compute_float64::<BINARY>(-10, 9223372036854776832, true), (-31703, 9223372036854776832) ); assert_eq!(compute_float64::<BINARY>(-10, 9223372036854777856, true), (1076, 1)); // Check other bases. assert_eq!(compute_float64::<BASE4>(-2, 144115188075855872, false), (1076, 0)); assert_eq!(compute_float64::<BASE4>(-2, 144115188075855888, false), (1076, 0)); assert_eq!(compute_float64::<BASE4>(-2, 144115188075855904, false), (1076, 1)); assert_eq!(compute_float64::<OCTAL>(-2, 576460752303423488, false), (1076, 0)); assert_eq!(compute_float64::<OCTAL>(-2, 576460752303423552, false), (1076, 0)); assert_eq!(compute_float64::<OCTAL>(-2, 576460752303423616, false), (1076, 1)); assert_eq!(compute_float64::<HEX>(-1, 144115188075855872, false), (1076, 0)); assert_eq!(compute_float64::<HEX>(-1, 144115188075855888, false), (1076, 0)); assert_eq!(compute_float64::<HEX>(-1, 144115188075855904, false), (1076, 1)); assert_eq!(compute_float64::<BASE32>(-1, 288230376151711744, false), (1076, 0)); assert_eq!(compute_float64::<BASE32>(-1, 288230376151711776, false), (1076, 0)); assert_eq!(compute_float64::<BASE32>(-1, 288230376151711808, false), (1076, 1)); } #[test] fn test_halfway_round_up() { // Halfway, round-up tests assert_eq!(compute_float64::<BINARY>(0, 9007199254740994, false), (1076, 1)); assert_eq!(compute_float64::<BINARY>(0, 9007199254740995, false), (1076, 2)); assert_eq!(compute_float64::<BINARY>(0, 9007199254740996, false), (1076, 2)); assert_eq!(compute_float64::<BINARY>(0, 18014398509481988, false), (1077, 1)); assert_eq!(compute_float64::<BINARY>(0, 18014398509481990, false), (1077, 2)); assert_eq!(compute_float64::<BINARY>(0, 18014398509481992, false), (1077, 2)); assert_eq!(compute_float64::<BINARY>(0, 9223372036854777856, false), (1086, 1)); assert_eq!(compute_float64::<BINARY>(0, 9223372036854778880, false), (1086, 2)); assert_eq!(compute_float64::<BINARY>(0, 9223372036854779904, false), (1086, 2)); // Add a 0 but say we're truncated. assert_eq!(compute_float64::<BINARY>(-10, 9223372036854777856, true), (1076, 1)); assert_eq!(compute_float64::<BINARY>(-10, 9223372036854778879, true), (1076, 1)); assert_eq!(compute_float64::<BINARY>(-10, 9223372036854778880, true), (1076, 2)); assert_eq!(compute_float64::<BINARY>(-10, 9223372036854779904, true), (1076, 2)); // Check other bases. assert_eq!(compute_float64::<BASE4>(-2, 144115188075855904, false), (1076, 1)); assert_eq!(compute_float64::<BASE4>(-2, 144115188075855920, false), (1076, 2)); assert_eq!(compute_float64::<BASE4>(-2, 144115188075855936, false), (1076, 2)); assert_eq!(compute_float64::<OCTAL>(-2, 576460752303423616, false), (1076, 1)); assert_eq!(compute_float64::<OCTAL>(-2, 576460752303423680, false), (1076, 2)); assert_eq!(compute_float64::<OCTAL>(-2, 576460752303423744, false), (1076, 2)); assert_eq!(compute_float64::<HEX>(-1, 144115188075855904, false), (1076, 1)); assert_eq!(compute_float64::<HEX>(-1, 144115188075855920, false), (1076, 2)); assert_eq!(compute_float64::<HEX>(-1, 144115188075855936, false), (1076, 2)); assert_eq!(compute_float64::<BASE32>(-1, 288230376151711808, false), (1076, 1)); assert_eq!(compute_float64::<BASE32>(-1, 288230376151711840, false), (1076, 2)); assert_eq!(compute_float64::<BASE32>(-1, 288230376151711872, false), (1076, 2)); } fn compute_float64_slow<const FORMAT: u128>( integer: &[u8], fraction: Option<&[u8]>, exponent: i64, ) -> (i32, u64) { let num = Number { exponent, mantissa: 0, is_negative: false, many_digits: false, integer, fraction, }; let fp = slow_binary::<f64, FORMAT>(num); (fp.exp, fp.mant) } #[test] fn test_slow() { let i = b"100000000000000000000000000000000000000000000000000001"; let f = b"0000000000000"; assert_eq!(compute_float64_slow::<BINARY>(i, Some(f), -10), (1076, 0)); let i = b"100000000000000000000000000000000000000000000000000001"; let f = b"000000000000000000001"; assert_eq!(compute_float64_slow::<BINARY>(i, Some(f), -10), (1076, 1)); let i = b"100000000000000000000000000000000000000000000000000001"; let f = b"000000000000010000000"; assert_eq!(compute_float64_slow::<BINARY>(i, Some(f), -10), (1076, 1)); }