// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package eval
import (
"bignum";
"testing";
)
var undefined = "undefined"
var typeAsExpr = "type .* used as expression"
var badCharLit = "character literal"
var illegalEscape = "illegal char escape"
var opTypes = "illegal (operand|argument) type|cannot index into"
var badAddrOf = "cannot take the address"
var constantTruncated = "constant [^ ]* truncated"
var constantUnderflows = "constant [^ ]* underflows"
var constantOverflows = "constant [^ ]* overflows"
var implLimit = "implementation limit"
var mustBeUnsigned = "must be unsigned"
var divByZero = "divide by zero"
var hugeInteger = bignum.Int(1).Shl(64)
var exprTests = []test{
Val("i", 1),
CErr("zzz", undefined),
// TODO(austin) Test variable in constant context
//CErr("t", typeAsExpr),
Val("'a'", bignum.Int('a')),
Val("'\\uffff'", bignum.Int('\uffff')),
Val("'\\n'", bignum.Int('\n')),
CErr("''+x", badCharLit),
// Produces two parse errors
//CErr("'''", ""),
CErr("'\n'", badCharLit),
CErr("'\\z'", illegalEscape),
CErr("'ab'", badCharLit),
Val("1.0", bignum.Rat(1, 1)),
Val("1.", bignum.Rat(1, 1)),
Val(".1", bignum.Rat(1, 10)),
Val("1e2", bignum.Rat(100, 1)),
Val("\"abc\"", "abc"),
Val("\"\"", ""),
Val("\"\\n\\\"\"", "\n\""),
CErr("\"\\z\"", illegalEscape),
CErr("\"abc", "string not terminated"),
Val("\"abc\" \"def\"", "abcdef"),
CErr("\"abc\" \"\\z\"", illegalEscape),
Val("(i)", 1),
Val("ai[0]", 1),
Val("(&ai)[0]", 1),
Val("ai[1]", 2),
Val("ai[i]", 2),
Val("ai[u]", 2),
CErr("ai[f]", opTypes),
CErr("ai[0][0]", opTypes),
CErr("ai[2]", "index 2 exceeds"),
CErr("ai[1+1]", "index 2 exceeds"),
CErr("ai[-1]", "negative index"),
RErr("ai[i+i]", "index 2 exceeds"),
RErr("ai[-i]", "negative index"),
CErr("i[0]", opTypes),
CErr("f[0]", opTypes),
Val("aai[0][0]", 1),
Val("aai[1][1]", 4),
CErr("aai[2][0]", "index 2 exceeds"),
CErr("aai[0][2]", "index 2 exceeds"),
Val("sli[0]", 1),
Val("sli[1]", 2),
CErr("sli[-1]", "negative index"),
RErr("sli[-i]", "negative index"),
RErr("sli[2]", "index 2 exceeds"),
Val("s[0]", uint8('a')),
Val("s[1]", uint8('b')),
CErr("s[-1]", "negative index"),
RErr("s[-i]", "negative index"),
RErr("s[3]", "index 3 exceeds"),
CErr("1(2)", "cannot call"),
CErr("fn(1,2)", "too many"),
CErr("fn()", "not enough"),
CErr("fn(true)", opTypes),
CErr("fn(true)", "function call"),
// Single argument functions don't say which argument.
//CErr("fn(true)", "argument 1"),
Val("fn(1)", 2),
Val("fn(1.0)", 2),
CErr("fn(1.5)", constantTruncated),
Val("fn(i)", 2),
CErr("fn(u)", opTypes),
CErr("void()+2", opTypes),
CErr("oneTwo()+2", opTypes),
Val("cap(ai)", 2),
Val("cap(&ai)", 2),
Val("cap(aai)", 2),
Val("cap(sli)", 3),
CErr("cap(0)", opTypes),
CErr("cap(i)", opTypes),
CErr("cap(s)", opTypes),
Val("len(s)", 3),
Val("len(ai)", 2),
Val("len(&ai)", 2),
Val("len(aai)", 2),
Val("len(sli)", 2),
// TODO(austin) Test len of map
CErr("len(0)", opTypes),
CErr("len(i)", opTypes),
CErr("*i", opTypes),
Val("*&i", 1),
Val("*&(i)", 1),
CErr("&1", badAddrOf),
CErr("&c", badAddrOf),
Val("*(&ai[0])", 1),
Val("+1", bignum.Int(+1)),
Val("+1.0", bignum.Rat(1, 1)),
CErr("+\"x\"", opTypes),
Val("-42", bignum.Int(-42)),
Val("-i", -1),
Val("-f", -1.0),
// 6g bug?
//Val("-(f-1)", -0.0),
CErr("-\"x\"", opTypes),
// TODO(austin) Test unary !
Val("^2", bignum.Int(^2)),
Val("^(-2)", bignum.Int(^(-2))),
CErr("^2.0", opTypes),
CErr("^2.5", opTypes),
Val("^i", ^1),
Val("^u", ^uint(1)),
CErr("^f", opTypes),
Val("1+i", 2),
Val("1+u", uint(2)),
Val("3.0+i", 4),
Val("1+1", bignum.Int(2)),
Val("f+f", 2.0),
Val("1+f", 2.0),
Val("1.0+1", bignum.Rat(2, 1)),
Val("\"abc\" + \"def\"", "abcdef"),
CErr("i+u", opTypes),
CErr("-1+u", constantUnderflows),
// TODO(austin) Test named types
Val("2-1", bignum.Int(1)),
Val("2.0-1", bignum.Rat(1, 1)),
Val("f-2", -1.0),
// TOOD(austin) bignum can't do negative 0?
//Val("-0.0", XXX),
Val("2*2", bignum.Int(4)),
Val("2*i", 2),
Val("3/2", bignum.Int(1)),
Val("3/i", 3),
CErr("1/0", divByZero),
CErr("1.0/0", divByZero),
RErr("i/0", divByZero),
Val("3%2", bignum.Int(1)),
Val("i%2", 1),
CErr("3%0", divByZero),
CErr("3.0%0", opTypes),
RErr("i%0", divByZero),
// Examples from "Arithmetic operators"
Val("5/3", bignum.Int(1)),
Val("(i+4)/(i+2)", 1),
Val("5%3", bignum.Int(2)),
Val("(i+4)%(i+2)", 2),
Val("-5/3", bignum.Int(-1)),
Val("(i-6)/(i+2)", -1),
Val("-5%3", bignum.Int(-2)),
Val("(i-6)%(i+2)", -2),
Val("5/-3", bignum.Int(-1)),
Val("(i+4)/(i-4)", -1),
Val("5%-3", bignum.Int(2)),
Val("(i+4)%(i-4)", 2),
Val("-5/-3", bignum.Int(1)),
Val("(i-6)/(i-4)", 1),
Val("-5%-3", bignum.Int(-2)),
Val("(i-6)%(i-4)", -2),
// Examples from "Arithmetic operators"
Val("11/4", bignum.Int(2)),
Val("(i+10)/4", 2),
Val("11%4", bignum.Int(3)),
Val("(i+10)%4", 3),
Val("11>>2", bignum.Int(2)),
Val("(i+10)>>2", 2),
Val("11&3", bignum.Int(3)),
Val("(i+10)&3", 3),
Val("-11/4", bignum.Int(-2)),
Val("(i-12)/4", -2),
Val("-11%4", bignum.Int(-3)),
Val("(i-12)%4", -3),
Val("-11>>2", bignum.Int(-3)),
Val("(i-12)>>2", -3),
Val("-11&3", bignum.Int(1)),
Val("(i-12)&3", 1),
// TODO(austin) Test bit ops
// For shift, we try nearly every combination of positive
// ideal int, negative ideal int, big ideal int, ideal
// fractional float, ideal non-fractional float, int, uint,
// and float.
Val("2<<2", bignum.Int(2<<2)),
CErr("2<<(-1)", constantUnderflows),
CErr("2<<0x10000000000000000", constantOverflows),
CErr("2<<2.5", constantTruncated),
Val("2<<2.0", bignum.Int(2<<2.0)),
CErr("2<<i", mustBeUnsigned),
Val("2<<u", 2<<1),
CErr("2<<f", opTypes),
Val("-2<<2", bignum.Int(-2<<2)),
CErr("-2<<(-1)", constantUnderflows),
CErr("-2<<0x10000000000000000", constantOverflows),
CErr("-2<<2.5", constantTruncated),
Val("-2<<2.0", bignum.Int(-2<<2.0)),
CErr("-2<<i", mustBeUnsigned),
Val("-2<<u", -2<<1),
CErr("-2<<f", opTypes),
Val("0x10000000000000000<<2", hugeInteger.Shl(2)),
CErr("0x10000000000000000<<(-1)", constantUnderflows),
CErr("0x10000000000000000<<0x10000000000000000", constantOverflows),
CErr("0x10000000000000000<<2.5", constantTruncated),
Val("0x10000000000000000<<2.0", hugeInteger.Shl(2)),
CErr("0x10000000000000000<<i", mustBeUnsigned),
CErr("0x10000000000000000<<u", constantOverflows),
CErr("0x10000000000000000<<f", opTypes),
CErr("2.5<<2", opTypes),
CErr("2.0<<2", opTypes),
Val("i<<2", 1<<2),
CErr("i<<(-1)", constantUnderflows),
CErr("i<<0x10000000000000000", constantOverflows),
CErr("i<<2.5", constantTruncated),
Val("i<<2.0", 1<<2),
CErr("i<<i", mustBeUnsigned),
Val("i<<u", 1<<1),
CErr("i<<f", opTypes),
Val("i<<u", 1<<1),
Val("u<<2", uint(1<<2)),
CErr("u<<(-1)", constantUnderflows),
CErr("u<<0x10000000000000000", constantOverflows),
CErr("u<<2.5", constantTruncated),
Val("u<<2.0", uint(1<<2)),
CErr("u<<i", mustBeUnsigned),
Val("u<<u", uint(1<<1)),
CErr("u<<f", opTypes),
Val("u<<u", uint(1<<1)),
CErr("f<<2", opTypes),
// <, <=, >, >=
Val("1<2", 1 < 2),
Val("1<=2", 1 <= 2),
Val("2<=2", 2 <= 2),
Val("1>2", 1 > 2),
Val("1>=2", 1 >= 2),
Val("2>=2", 2 >= 2),
Val("i<2", 1 < 2),
Val("i<=2", 1 <= 2),
Val("i+1<=2", 2 <= 2),
Val("i>2", 1 > 2),
Val("i>=2", 1 >= 2),
Val("i+1>=2", 2 >= 2),
Val("u<2", 1 < 2),
Val("f<2", 1 < 2),
Val("s<\"b\"", true),
Val("s<\"a\"", false),
Val("s<=\"abc\"", true),
Val("s>\"aa\"", true),
Val("s>\"ac\"", false),
Val("s>=\"abc\"", true),
CErr("i<u", opTypes),
CErr("i<f", opTypes),
CErr("i<s", opTypes),
CErr("&i<&i", opTypes),
CErr("ai<ai", opTypes),
// ==, !=
Val("1==1", true),
Val("1!=1", false),
Val("1==2", false),
Val("1!=2", true),
Val("1.0==1", true),
Val("1.5==1", false),
Val("i==1", true),
Val("i!=1", false),
Val("i==2", false),
Val("i!=2", true),
Val("u==1", true),
Val("f==1", true),
Val("s==\"abc\"", true),
Val("s!=\"abc\"", false),
Val("s==\"abcd\"", false),
Val("s!=\"abcd\"", true),
Val("&i==&i", true),
Val("&i==&i2", false),
Val("fn==fn", true),
Val("fn==func(int)int{return 0}", false),
CErr("i==u", opTypes),
CErr("i==f", opTypes),
CErr("&i==&f", opTypes),
CErr("ai==ai", opTypes),
CErr("t==t", opTypes),
CErr("fn==oneTwo", opTypes),
}
func TestExpr(t *testing.T) { runTests(t, "exprTests", exprTests) }
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