#![feature(rustc_private)] extern crate clippy_lints; extern crate rustc; extern crate rustc_const_eval; extern crate rustc_const_math; extern crate syntax; use clippy_lints::consts::{constant_simple, Constant, FloatWidth}; use rustc_const_math::ConstInt; use rustc::hir::*; use syntax::ast::{LitIntType, LitKind, NodeId, StrStyle}; use syntax::codemap::{Spanned, COMMAND_LINE_SP}; use syntax::symbol::Symbol; use syntax::ptr::P; use syntax::util::ThinVec; fn spanned(t: T) -> Spanned { Spanned { node: t, span: COMMAND_LINE_SP, } } fn expr(n: Expr_) -> Expr { Expr { id: NodeId::new(1), node: n, span: COMMAND_LINE_SP, attrs: ThinVec::new(), } } fn lit(l: LitKind) -> Expr { expr(ExprLit(P(spanned(l)))) } fn binop(op: BinOp_, l: Expr, r: Expr) -> Expr { expr(ExprBinary(spanned(op), P(l), P(r))) } fn check(expect: Constant, expr: &Expr) { assert_eq!(Some(expect), constant_simple(expr)) } const TRUE: Constant = Constant::Bool(true); const FALSE: Constant = Constant::Bool(false); const ZERO: Constant = Constant::Int(ConstInt::Infer(0)); const ONE: Constant = Constant::Int(ConstInt::Infer(1)); const TWO: Constant = Constant::Int(ConstInt::Infer(2)); #[test] fn test_lit() { check(TRUE, &lit(LitKind::Bool(true))); check(FALSE, &lit(LitKind::Bool(false))); check(ZERO, &lit(LitKind::Int(0, LitIntType::Unsuffixed))); check(Constant::Str("cool!".into(), StrStyle::Cooked), &lit(LitKind::Str(Symbol::intern("cool!"), StrStyle::Cooked))); } #[test] fn test_ops() { check(TRUE, &binop(BiOr, lit(LitKind::Bool(false)), lit(LitKind::Bool(true)))); check(FALSE, &binop(BiAnd, lit(LitKind::Bool(false)), lit(LitKind::Bool(true)))); let litzero = lit(LitKind::Int(0, LitIntType::Unsuffixed)); let litone = lit(LitKind::Int(1, LitIntType::Unsuffixed)); check(TRUE, &binop(BiEq, litzero.clone(), litzero.clone())); check(TRUE, &binop(BiGe, litzero.clone(), litzero.clone())); check(TRUE, &binop(BiLe, litzero.clone(), litzero.clone())); check(FALSE, &binop(BiNe, litzero.clone(), litzero.clone())); check(FALSE, &binop(BiGt, litzero.clone(), litzero.clone())); check(FALSE, &binop(BiLt, litzero.clone(), litzero.clone())); check(ZERO, &binop(BiAdd, litzero.clone(), litzero.clone())); check(TWO, &binop(BiAdd, litone.clone(), litone.clone())); check(ONE, &binop(BiSub, litone.clone(), litzero.clone())); check(ONE, &binop(BiMul, litone.clone(), litone.clone())); check(ONE, &binop(BiDiv, litone.clone(), litone.clone())); let half_any = Constant::Float("0.5".into(), FloatWidth::Any); let half32 = Constant::Float("0.5".into(), FloatWidth::F32); let half64 = Constant::Float("0.5".into(), FloatWidth::F64); let pos_zero = Constant::Float("0.0".into(), FloatWidth::F64); let neg_zero = Constant::Float("-0.0".into(), FloatWidth::F64); assert_eq!(pos_zero, pos_zero); assert_eq!(neg_zero, neg_zero); assert_eq!(None, pos_zero.partial_cmp(&neg_zero)); assert_eq!(half_any, half32); assert_eq!(half_any, half64); // for transitivity assert_eq!(half32, half64); assert_eq!(Constant::Int(ConstInt::Infer(0)), Constant::Int(ConstInt::U8(0))); assert_eq!(Constant::Int(ConstInt::Infer(0)), Constant::Int(ConstInt::I8(0))); assert_eq!(Constant::Int(ConstInt::InferSigned(-1)), Constant::Int(ConstInt::I8(-1))); }