# puremp
[](https://github.com/KarpelesLab/puremp/actions/workflows/ci.yml)
[](https://crates.io/crates/puremp)
[](https://docs.rs/puremp)
[](LICENSE)
Pure-Rust, MIT-licensed, arbitrary-precision arithmetic — **integers,
rationals, MPFR-class floating point, and base-10 decimals**, plus derived
**modular integers, complex numbers, polynomials, matrices, and intervals** —
with no foreign-code dependencies. Usable as a Rust crate, a C library, and a
command-line calculator.
## Why
A GMP + MPFR-class toolkit that is:
- **Pure, safe Rust** — no C, no inline assembly, no intrinsics. The only
`unsafe` in the crate is the opt-in C ABI module.
- **Clean-room & MIT-licensed** — algorithms come from the open literature
(Knuth; Brent & Zimmermann's *Modern Computer Arithmetic*; the HAC), never
from GMP/MPFR source. Use it anywhere, including closed-source projects.
- **`no_std` + `alloc`** — runs on bare metal with an allocator; no OS
assumptions in the core. Verified on 32-bit `thumbv7em-none-eabi` in CI.
## Quick start (Rust)
```toml
[dependencies]
puremp = "0"
```
```rust
use puremp::{Int, Rational};
let big = Int::from_i64(2).pow(100);
assert_eq!(big.to_string(), "1267650600228229401496703205376");
let sum = Rational::new(Int::from_i64(1), Int::from_i64(2))? // 1/2
.add(&Rational::new(Int::from_i64(1), Int::from_i64(3))?); // + 1/3
assert_eq!(sum.to_string(), "5/6");
# Ok::<(), puremp::Error>(())
```
## Quick start (CLI)
```console
$ cargo run --bin puremp
puremp> 2 ** 100
1267650600228229401496703205376
puremp> x = 1000
puremp> x * x - 1
999999
puremp> (2**64) * (2**64)
340282366920938463463374607431768211456
puremp> :quit
```
Supports `+ - * / % **`, parentheses, unary minus, decimal literals, and
`name = expr` variables (`/` and `%` are truncated integer division).
## Quick start (C)
Build the static and/or shared library and link against the header in
[`include/puremp.h`](include/puremp.h):
```console
$ cargo rustc --lib --release --features ffi --crate-type staticlib
$ cargo rustc --lib --release --features ffi --crate-type cdylib
$ cc myprog.c -I include target/release/libpuremp.a -lpthread -ldl -lm -o myprog
```
```c
#include "puremp.h"
#include <stdio.h>
int main(void) {
PurempInt *two = puremp_int_from_i64(2);
PurempInt *big = puremp_int_pow(two, 100);
char *s = puremp_int_to_string(big);
printf("2^100 = %s\n", s);
puremp_string_free(s);
puremp_int_free(big);
puremp_int_free(two);
return 0;
}
```
## Feature flags
| `std` | ✔ | `std::error::Error`, the CLI, system I/O (implies `alloc`) |
| `alloc` | ✔ | Heap-backed arbitrary-precision types (required by every layer) |
| `int` | ✔ | `Nat` and `Int` |
| `rational` | ✔ | `Rational` and `InfRational` (implies `int`) |
| `dyadic` | ✔ | `Dyadic` — exact `n·2⁻ᵏ` binary fractions (implies `int`) |
| `decimal` | ✔ | `Decimal` — exact base-10 floating point (implies `int`) |
| `complex` | ✔ | `Complex<T>` — generic complex / Gaussian integers |
| `poly` | ✔ | `Poly<T>` — generic univariate polynomials |
| `matrix` | ✔ | `Matrix<T>` — dense matrices with exact linear algebra |
| `interval` | ✔ | `Interval` — outward-rounded interval arithmetic (implies `float`) |
| `algebraic` | ✔ | `Quadratic` (ℚ(√d)) and general real `Algebraic` numbers |
| `float` | ✔ | Separable `Float` + `FixedFloat` layer (implies `int`); not part of the core contract, disable via `--no-default-features` |
| `num-traits` | | Implements `num-traits` interfaces for `Int`/`Rational`/`Nat`/`Decimal`/`Complex` |
| `ffi` | | The C ABI module (`include/puremp.h`) |
| `cli` | ✔ | The `puremp` binary |
Beyond the base types, `Int`/`Rational` provide a number-theory toolkit —
`factorize`, `sqrt_mod` (Tonelli–Shanks), `jacobi`/`legendre`, `crt`,
`random_prime`, `factorial`/`binomial`/`fibonacci`, and continued-fraction
`approximate` — plus `ModInt` for modular arithmetic.
For a bare `no_std` build: `--no-default-features` (add `--features int` for the
integer types).
## Design & provenance
Bottom-up layers, each building only on the ones below: machine-word carry
primitives (`adc`/`sbb`/`mac`) → unsigned magnitudes (`Nat`, home of the hard
algorithms) → tagged signed `Int` → `Rational`, with the optional `Float` and
the derived types layered on top. Signed integers inline single-limb magnitudes
(no heap allocation until a value exceeds 64 bits).
The implementation is **clean-room**: GMP and MPFR are LGPL and their source is
never consulted. Algorithms come from the open literature —
- Knuth, *TAOCP* Vol. 2 §4.3 (schoolbook arithmetic; Algorithm D for division);
- Brent & Zimmermann, *Modern Computer Arithmetic* (sub-quadratic multiply/
divide, GCD, base conversion);
- Menezes, van Oorschot & Vanstone, *Handbook of Applied Cryptography*;
- primary papers: Karatsuba; Toom–Cook; Burnikel–Ziegler; Möller–Granlund;
Faddeev–LeVerrier (algebraic numbers); Sturm sequences (real-root isolation).
Correctness is checked against published values and, in the dev-only test
harness, a trusted reference — never a runtime dependency.
**Non-goals:** constant-time / side-channel resistance across the general API
(for constant-time crypto see the sibling `purecrypto` crate); drop-in GMP/MPFR
C-header compatibility (puremp ships its own cleaner C ABI).
Run `cargo run --release --example bench` for a throughput harness across the
core operations and the derived types.
**Known future optimizations** (correct today, just not maximally fast):
- **`nth_root_floor`** (for `k > 2`) still uses a bitwise search with a full
`pow(k)` per candidate bit; a Newton/recursive `k`th root would match the
`O(M(n))` integer square root.
- A **half-GCD** for asymptotically faster `Rational` reduction; allocation-
reducing **scratch buffers** in the recursive multiply/divide code; and a
**subresultant PRS** to tame Sturm-sequence coefficient growth for high-degree
`Algebraic` operations.
## License
MIT — see [`LICENSE`](LICENSE).