mirror of
https://github.com/italicsjenga/gba.git
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d52d627113
* Remove cargo-xbuild dev dependency As of Rust nightly 2020-07-15, we can set the default build target and build-std feature of cargo instead of relying on cargo-xbuild. Since the thumbv4-non-agb target is the default for all cargo commands, change the Rust snippets in Makefile.toml to cross-platform duckscript. The only uglyness we're left with is running the unit tests. We want to build and run the tests on the host archetecture. Create three platform overrides for Mac, Windows, Linux and set flags to override the default target triple and build-std option. * remove uneeded attribute From cargo: "the feature `cfg_target_vendor` has been stable since 1.33.0 and no longer requires an attribute to enable"
235 lines
6.2 KiB
Rust
235 lines
6.2 KiB
Rust
#![cfg_attr(not(test), no_std)]
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#![feature(asm)]
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#![allow(clippy::cast_lossless)]
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#![deny(clippy::float_arithmetic)]
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#![warn(missing_docs)]
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//! This crate helps you write GBA ROMs.
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//!
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//! ## SAFETY POLICY
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//!
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//! Some parts of this crate are safe wrappers around unsafe operations. This is
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//! good, and what you'd expect from a Rust crate.
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//!
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//! However, the safe wrappers all assume that you will _only_ attempt to
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//! execute this crate on a GBA or in a GBA Emulator.
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//!
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//! **Do not** use this crate in programs that aren't running on the GBA. If you
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//! do, it's a giant bag of Undefined Behavior.
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pub(crate) use gba_proc_macro::phantom_fields;
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pub(crate) use voladdress::{read_only::ROVolAddress, VolAddress, VolBlock};
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pub mod macros;
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pub mod base;
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pub mod bios;
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pub mod iwram;
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pub mod ewram;
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pub mod io;
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pub mod palram;
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pub mod vram;
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pub mod oam;
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pub mod rom;
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pub mod sram;
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pub mod mgba;
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extern "C" {
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/// This marks the end of the `.data` and `.bss` sections in IWRAM.
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///
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/// Memory in IWRAM _before_ this location is not free to use, you'll trash
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/// your globals and stuff. Memory here or after is freely available for use
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/// (careful that you don't run into your own stack of course).
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///
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/// The actual value is unimportant, you just want to use the _address of_
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/// this location as the start of your IWRAM usage.
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pub static __bss_end: u8;
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}
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newtype! {
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/// A color on the GBA is an RGB 5.5.5 within a `u16`
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#[derive(PartialOrd, Ord, Hash)]
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Color, pub u16
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}
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impl Color {
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/// Constructs a color from the channel values provided (should be 0..=31).
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///
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/// No actual checks are performed, so illegal channel values can overflow
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/// into each other and produce an unintended color.
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pub const fn from_rgb(r: u16, g: u16, b: u16) -> Color {
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Color(b << 10 | g << 5 | r)
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}
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}
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//
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// After here is totally unsorted nonsense
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//
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/// Performs unsigned divide and remainder, gives None if dividing by 0.
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pub fn divrem_u32(numer: u32, denom: u32) -> Option<(u32, u32)> {
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// TODO: const this? Requires const if
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if denom == 0 {
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None
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} else {
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Some(unsafe { divrem_u32_unchecked(numer, denom) })
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}
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}
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/// Performs divide and remainder, no check for 0 division.
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///
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/// # Safety
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///
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/// If you call this with a denominator of 0 the result is implementation
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/// defined (not literal UB) including but not limited to: an infinite loop,
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/// panic on overflow, or incorrect output.
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pub unsafe fn divrem_u32_unchecked(numer: u32, denom: u32) -> (u32, u32) {
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// TODO: const this? Requires const if
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if (numer >> 5) < denom {
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divrem_u32_simple(numer, denom)
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} else {
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divrem_u32_non_restoring(numer, denom)
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}
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}
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/// The simplest form of division. If N is too much larger than D this will be
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/// extremely slow. If N is close enough to D then it will likely be faster than
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/// the non_restoring form.
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fn divrem_u32_simple(mut numer: u32, denom: u32) -> (u32, u32) {
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// TODO: const this? Requires const if
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let mut quot = 0;
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while numer >= denom {
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numer -= denom;
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quot += 1;
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}
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(quot, numer)
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}
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/// Takes a fixed quantity of time based on the bit width of the number (in this
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/// case 32).
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fn divrem_u32_non_restoring(numer: u32, denom: u32) -> (u32, u32) {
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// TODO: const this? Requires const if
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let mut r: i64 = numer as i64;
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let d: i64 = (denom as i64) << 32;
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let mut q: u32 = 0;
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let mut i = 1 << 31;
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while i > 0 {
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if r >= 0 {
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q |= i;
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r = 2 * r - d;
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} else {
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r = 2 * r + d;
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}
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i >>= 1;
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}
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q -= !q;
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if r < 0 {
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q -= 1;
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r += d;
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}
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r >>= 32;
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// TODO: remove this once we've done more checks here.
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debug_assert!(r >= 0);
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debug_assert!(r <= core::u32::MAX as i64);
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(q, r as u32)
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}
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/// Performs signed divide and remainder, gives None if dividing by 0 or
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/// computing `MIN/-1`
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pub fn divrem_i32(numer: i32, denom: i32) -> Option<(i32, i32)> {
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if denom == 0 || (numer == core::i32::MIN && denom == -1) {
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None
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} else {
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Some(unsafe { divrem_i32_unchecked(numer, denom) })
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}
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}
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/// Performs signed divide and remainder, no check for 0 division or `MIN/-1`.
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///
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/// # Safety
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///
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/// * If you call this with a denominator of 0 the result is implementation
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/// defined (not literal UB) including but not limited to: an infinite loop,
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/// panic on overflow, or incorrect output.
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/// * If you call this with `MIN/-1` you'll get a panic in debug or just `MIN`
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/// in release (which is incorrect), because of how twos-compliment works.
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pub unsafe fn divrem_i32_unchecked(numer: i32, denom: i32) -> (i32, i32) {
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// TODO: const this? Requires const if
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let unsigned_numer = numer.abs() as u32;
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let unsigned_denom = denom.abs() as u32;
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let opposite_sign = (numer ^ denom) < 0;
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let (udiv, urem) = if (numer >> 5) < denom {
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divrem_u32_simple(unsigned_numer, unsigned_denom)
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} else {
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divrem_u32_non_restoring(unsigned_numer, unsigned_denom)
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};
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match (opposite_sign, numer < 0) {
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(true, true) => (-(udiv as i32), -(urem as i32)),
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(true, false) => (-(udiv as i32), urem as i32),
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(false, true) => (udiv as i32, -(urem as i32)),
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(false, false) => (udiv as i32, urem as i32),
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}
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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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use quickcheck::quickcheck;
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// We have an explicit property on the non_restoring division
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quickcheck! {
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fn divrem_u32_non_restoring_prop(num: u32, denom: u32) -> bool {
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if denom > 0 {
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divrem_u32_non_restoring(num, denom) == (num / denom, num % denom)
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} else {
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true
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}
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}
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}
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// We have an explicit property on the simple division
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quickcheck! {
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fn divrem_u32_simple_prop(num: u32, denom: u32) -> bool {
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if denom > 0 {
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divrem_u32_simple(num, denom) == (num / denom, num % denom)
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} else {
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true
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}
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}
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}
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// Test the u32 wrapper
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quickcheck! {
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fn divrem_u32_prop(num: u32, denom: u32) -> bool {
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if denom > 0 {
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divrem_u32(num, denom).unwrap() == (num / denom, num % denom)
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} else {
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divrem_u32(num, denom).is_none()
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}
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}
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}
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// test the i32 wrapper
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quickcheck! {
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fn divrem_i32_prop(num: i32, denom: i32) -> bool {
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if denom == 0 || num == core::i32::MIN && denom == -1 {
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divrem_i32(num, denom).is_none()
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} else {
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divrem_i32(num, denom).unwrap() == (num / denom, num % denom)
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}
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}
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}
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}
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*/
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