internal/refactor/inline/falcon_test.go - tools - Git at Google

 // Copyright 2023 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 inline_test

 import "testing"

 // Testcases mostly come in pairs, of a success and a failure
 // to substitute based on specific constant argument values.

 func TestFalconStringIndex(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Non-negative string index.",
 			`func f(i int) byte { return s[i] }; var s string`,
 			`func _() { f(0) }`,
 			`func _() { _ = s[0] }`,
 		},
 		{
 			"Negative string index.",
 			`func f(i int) byte { return s[i] }; var s string`,
 			`func _() { f(-1) }`,
 			`func _() {
 	var i int = -1
 	_ = s[i]
 }`,
 		},
 		{
 			"String index in range.",
 			`func f(s string, i int) byte { return s[i] }`,
 			`func _() { f("-", 0) }`,
 			`func _() { _ = "-"[0] }`,
 		},
 		{
 			"String index out of range.",
 			`func f(s string, i int) byte { return s[i] }`,
 			`func _() { f("-", 1) }`,
 			`func _() {
 	var (
 		s string = "-"
 		i int    = 1
 	)
 	_ = s[i]
 }`,
 		},
 		{
 			"Remove known prefix (OK)",
 			`func f(s, prefix string) string { return s[:len(prefix)] }`,
 			`func _() { f("", "") }`,
 			`func _() { _ = ""[:len("")] }`,
 		},
 		{
 			"Remove not-a-prefix (out of range)",
 			`func f(s, prefix string) string { return s[:len(prefix)] }`,
 			`func _() { f("", "pre") }`,
 			`func _() {
 	var s, prefix string = "", "pre"
 	_ = s[:len(prefix)]
 }`,
 		},
 	})
 }

 func TestFalconSliceIndices(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Monotonic (0<=i<=j) slice indices (len unknown).",
 			`func f(i, j int) []int { return s[i:j] }; var s []int`,
 			`func _() { f(0, 1) }`,
 			`func _() { _ = s[0:1] }`,
 		},
 		{
 			"Non-monotonic slice indices (len unknown).",
 			`func f(i, j int) []int { return s[i:j] }; var s []int`,
 			`func _() { f(1, 0) }`,
 			`func _() {
 	var i, j int = 1, 0
 	_ = s[i:j]
 }`,
 		},
 		{
 			"Negative slice index.",
 			`func f(i, j int) []int { return s[i:j] }; var s []int`,
 			`func _() { f(-1, 1) }`,
 			`func _() {
 	var i, j int = -1, 1
 	_ = s[i:j]
 }`,
 		},
 	})
 }

 func TestFalconMapKeys(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Unique map keys (int)",
 			`func f(x int) { _ = map[int]bool{1: true, x: true} }`,
 			`func _() { f(2) }`,
 			`func _() { _ = map[int]bool{1: true, 2: true} }`,
 		},
 		{
 			"Duplicate map keys (int)",
 			`func f(x int) { _ = map[int]bool{1: true, x: true} }`,
 			`func _() { f(1) }`,
 			`func _() {
 	var x int = 1
 	_ = map[int]bool{1: true, x: true}
 }`,
 		},
 		{
 			"Unique map keys (varied built-in types)",
 			`func f(x int16) { _ = map[any]bool{1: true, x: true} }`,
 			`func _() { f(2) }`,
 			`func _() { _ = map[any]bool{1: true, int16(2): true} }`,
 		},
 		{
 			"Duplicate map keys (varied built-in types)",
 			`func f(x int16) { _ = map[any]bool{1: true, x: true} }`,
 			`func _() { f(1) }`,
 			`func _() { _ = map[any]bool{1: true, int16(1): true} }`,
 		},
 		{
 			"Unique map keys (varied user-defined types)",
 			`func f(x myint) { _ = map[any]bool{1: true, x: true} }; type myint int`,
 			`func _() { f(2) }`,
 			`func _() { _ = map[any]bool{1: true, myint(2): true} }`,
 		},
 		{
 			"Duplicate map keys (varied user-defined types)",
 			`func f(x myint, y myint2) { _ = map[any]bool{x: true, y: true} }; type (myint int; myint2 int)`,
 			`func _() { f(1, 1) }`,
 			`func _() {
 	var (
 		x myint  = 1
 		y myint2 = 1
 	)
 	_ = map[any]bool{x: true, y: true}
 }`,
 		},
 		{
 			"Duplicate map keys (user-defined alias to built-in)",
 			`func f(x myint, y int) { _ = map[any]bool{x: true, y: true} }; type myint = int`,
 			`func _() { f(1, 1) }`,
 			`func _() {
 	var (
 		x myint = 1
 		y int   = 1
 	)
 	_ = map[any]bool{x: true, y: true}
 }`,
 		},
 	})
 }

 func TestFalconSwitchCases(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Unique switch cases (int).",
 			`func f(x int) { switch 0 { case x: case 1: } }`,
 			`func _() { f(2) }`,
 			`func _() {
 	switch 0 {
 	case 2:
 	case 1:
 	}
 }`,
 		},
 		{
 			"Duplicate switch cases (int).",
 			`func f(x int) { switch 0 { case x: case 1: } }`,
 			`func _() { f(1) }`,
 			`func _() {
 	var x int = 1
 	switch 0 {
 	case x:
 	case 1:
 	}
 }`,
 		},
 		{
 			"Unique switch cases (varied built-in types).",
 			`func f(x int) { switch any(nil) { case x: case int16(1): } }`,
 			`func _() { f(2) }`,
 			`func _() {
 	switch any(nil) {
 	case 2:
 	case int16(1):
 	}
 }`,
 		},
 		{
 			"Duplicate switch cases (varied built-in types).",
 			`func f(x int) { switch any(nil) { case x: case int16(1): } }`,
 			`func _() { f(1) }`,
 			`func _() {
 	switch any(nil) {
 	case 1:
 	case int16(1):
 	}
 }`,
 		},
 	})
 }

 func TestFalconDivision(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Division by two.",
 			`func f(x, y int) int { return x / y }`,
 			`func _() { f(1, 2) }`,
 			`func _() { _ = 1 / 2 }`,
 		},
 		{
 			"Division by zero.",
 			`func f(x, y int) int { return x / y }`,
 			`func _() { f(1, 0) }`,
 			`func _() {
 	var x, y int = 1, 0
 	_ = x / y
 }`,
 		},
 		{
 			"Division by two (statement).",
 			`func f(x, y int) { x /= y }`,
 			`func _() { f(1, 2) }`,
 			`func _() {
 	var x int = 1
 	x /= 2
 }`,
 		},
 		{
 			"Division by zero (statement).",
 			`func f(x, y int) { x /= y }`,
 			`func _() { f(1, 0) }`,
 			`func _() {
 	var x, y int = 1, 0
 	x /= y
 }`,
 		},
 		{
 			"Division of minint by two (ok).",
 			`func f(x, y int32) { _ = x / y }`,
 			`func _() { f(-0x80000000, 2) }`,
 			`func _() { _ = int32(-0x80000000) / int32(2) }`,
 		},
 		{
 			"Division of minint by -1 (overflow).",
 			`func f(x, y int32) { _ = x / y }`,
 			`func _() { f(-0x80000000, -1) }`,
 			`func _() {
 	var x, y int32 = -0x80000000, -1
 	_ = x / y
 }`,
 		},
 	})
 }

 func TestFalconMinusMinInt(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Negation of maxint.",
 			`func f(x int32) int32 { return -x }`,
 			`func _() { f(0x7fffffff) }`,
 			`func _() { _ = -int32(0x7fffffff) }`,
 		},
 		{
 			"Negation of minint.",
 			`func f(x int32) int32 { return -x }`,
 			`func _() { f(-0x80000000) }`,
 			`func _() {
 	var x int32 = -0x80000000
 	_ = -x
 }`,
 		},
 	})
 }

 func TestFalconArithmeticOverflow(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Addition without overflow.",
 			`func f(x, y int32) int32 { return x + y }`,
 			`func _() { f(100, 200) }`,
 			`func _() { _ = int32(100) + int32(200) }`,
 		},
 		{
 			"Addition with overflow.",
 			`func f(x, y int32) int32 { return x + y }`,
 			`func _() { f(1<<30, 1<<30) }`,
 			`func _() {
 	var x, y int32 = 1 << 30, 1 << 30
 	_ = x + y
 }`,
 		},
 		{
 			"Conversion in range.",
 			`func f(x int) int8 { return int8(x) }`,
 			`func _() { f(123) }`,
 			`func _() { _ = int8(123) }`,
 		},
 		{
 			"Conversion out of range.",
 			`func f(x int) int8 { return int8(x) }`,
 			`func _() { f(456) }`,
 			`func _() {
 	var x int = 456
 	_ = int8(x)
 }`,
 		},
 	})
 }

 func TestFalconComplex(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Complex arithmetic (good).",
 			`func f(re, im float64, z complex128) byte { return "x"[int(real(complex(re, im)*complex(re, -im)-z))] }`,
 			`func _() { f(1, 2, 5+0i) }`,
 			`func _() { _ = "x"[int(real(complex(float64(1), float64(2))*complex(float64(1), -float64(2))-(5+0i)))] }`,
 		},
 		{
 			"Complex arithmetic (bad).",
 			`func f(re, im float64, z complex128) byte { return "x"[int(real(complex(re, im)*complex(re, -im)-z))] }`,
 			`func _() { f(1, 3, 5+0i) }`,
 			`func _() {
 	var (
 		re, im float64    = 1, 3
 		z      complex128 = 5 + 0i
 	)
 	_ = "x"[int(real(complex(re, im)*complex(re, -im)-z))]
 }`,
 		},
 	})
 }
 func TestFalconMisc(t *testing.T) {
 	runTests(t, []testcase{
 		{
 			"Compound constant expression (good).",
 			`func f(x, y string, i, j int) byte { return x[i*len(y)+j] }`,
 			`func _() { f("abc", "xy", 2, -3) }`,
 			`func _() { _ = "abc"[2*len("xy")+-3] }`,
 		},
 		{
 			"Compound constant expression (index out of range).",
 			`func f(x, y string, i, j int) byte { return x[i*len(y)+j] }`,
 			`func _() { f("abc", "xy", 4, -3) }`,
 			`func _() {
 	var (
 		x, y string = "abc", "xy"
 		i, j int    = 4, -3
 	)
 	_ = x[i*len(y)+j]
 }`,
 		},
 		{
 			"Constraints within nested functions (good).",
 			`func f(x int) { _ = func() { _ = [1]int{}[x] } }`,
 			`func _() { f(0) }`,
 			`func _() { _ = func() { _ = [1]int{}[0] } }`,
 		},
 		{
 			"Constraints within nested functions (bad).",
 			`func f(x int) { _ = func() { _ = [1]int{}[x] } }`,
 			`func _() { f(1) }`,
 			`func _() {
 	var x int = 1
 	_ = func() { _ = [1]int{}[x] }
 }`,
 		},
 		{
 			"Falcon violation rejects only the constant arguments (x, z).",
 			`func f(x, y, z string) string { return x[:2] + y + z[:2] }; var b string`,
 			`func _() { f("a", b, "c") }`,
 			`func _() {
 	var x, z string = "a", "c"
 	_ = x[:2] + b + z[:2]
 }`,
 		},
 	})
 }
	// Copyright 2023 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 inline_test

	import "testing"

	// Testcases mostly come in pairs, of a success and a failure
	// to substitute based on specific constant argument values.

	func TestFalconStringIndex(t *testing.T) {
	runTests(t, []testcase{
	{
	"Non-negative string index.",
	`func f(i int) byte { return s[i] }; var s string`,
	`func _() { f(0) }`,
	`func _() { _ = s[0] }`,
	},
	{
	"Negative string index.",
	`func f(i int) byte { return s[i] }; var s string`,
	`func _() { f(-1) }`,
	`func _() {
	var i int = -1
	_ = s[i]
	}`,
	},
	{
	"String index in range.",
	`func f(s string, i int) byte { return s[i] }`,
	`func _() { f("-", 0) }`,
	`func _() { _ = "-"[0] }`,
	},
	{
	"String index out of range.",
	`func f(s string, i int) byte { return s[i] }`,
	`func _() { f("-", 1) }`,
	`func _() {
	var (
	s string = "-"
	i int = 1
	)
	_ = s[i]
	}`,
	},
	{
	"Remove known prefix (OK)",
	`func f(s, prefix string) string { return s[:len(prefix)] }`,
	`func _() { f("", "") }`,
	`func _() { _ = ""[:len("")] }`,
	},
	{
	"Remove not-a-prefix (out of range)",
	`func f(s, prefix string) string { return s[:len(prefix)] }`,
	`func _() { f("", "pre") }`,
	`func _() {
	var s, prefix string = "", "pre"
	_ = s[:len(prefix)]
	}`,
	},
	})
	}

	func TestFalconSliceIndices(t *testing.T) {
	runTests(t, []testcase{
	{
	"Monotonic (0<=i<=j) slice indices (len unknown).",
	`func f(i, j int) []int { return s[i:j] }; var s []int`,
	`func _() { f(0, 1) }`,
	`func _() { _ = s[0:1] }`,
	},
	{
	"Non-monotonic slice indices (len unknown).",
	`func f(i, j int) []int { return s[i:j] }; var s []int`,
	`func _() { f(1, 0) }`,
	`func _() {
	var i, j int = 1, 0
	_ = s[i:j]
	}`,
	},
	{
	"Negative slice index.",
	`func f(i, j int) []int { return s[i:j] }; var s []int`,
	`func _() { f(-1, 1) }`,
	`func _() {
	var i, j int = -1, 1
	_ = s[i:j]
	}`,
	},
	})
	}

	func TestFalconMapKeys(t *testing.T) {
	runTests(t, []testcase{
	{
	"Unique map keys (int)",
	`func f(x int) { _ = map[int]bool{1: true, x: true} }`,
	`func _() { f(2) }`,
	`func _() { _ = map[int]bool{1: true, 2: true} }`,
	},
	{
	"Duplicate map keys (int)",
	`func f(x int) { _ = map[int]bool{1: true, x: true} }`,
	`func _() { f(1) }`,
	`func _() {
	var x int = 1
	_ = map[int]bool{1: true, x: true}
	}`,
	},
	{
	"Unique map keys (varied built-in types)",
	`func f(x int16) { _ = map[any]bool{1: true, x: true} }`,
	`func _() { f(2) }`,
	`func _() { _ = map[any]bool{1: true, int16(2): true} }`,
	},
	{
	"Duplicate map keys (varied built-in types)",
	`func f(x int16) { _ = map[any]bool{1: true, x: true} }`,
	`func _() { f(1) }`,
	`func _() { _ = map[any]bool{1: true, int16(1): true} }`,
	},
	{
	"Unique map keys (varied user-defined types)",
	`func f(x myint) { _ = map[any]bool{1: true, x: true} }; type myint int`,
	`func _() { f(2) }`,
	`func _() { _ = map[any]bool{1: true, myint(2): true} }`,
	},
	{
	"Duplicate map keys (varied user-defined types)",
	`func f(x myint, y myint2) { _ = map[any]bool{x: true, y: true} }; type (myint int; myint2 int)`,
	`func _() { f(1, 1) }`,
	`func _() {
	var (
	x myint = 1
	y myint2 = 1
	)
	_ = map[any]bool{x: true, y: true}
	}`,
	},
	{
	"Duplicate map keys (user-defined alias to built-in)",
	`func f(x myint, y int) { _ = map[any]bool{x: true, y: true} }; type myint = int`,
	`func _() { f(1, 1) }`,
	`func _() {
	var (
	x myint = 1
	y int = 1
	)
	_ = map[any]bool{x: true, y: true}
	}`,
	},
	})
	}

	func TestFalconSwitchCases(t *testing.T) {
	runTests(t, []testcase{
	{
	"Unique switch cases (int).",
	`func f(x int) { switch 0 { case x: case 1: } }`,
	`func _() { f(2) }`,
	`func _() {
	switch 0 {
	case 2:
	case 1:
	}
	}`,
	},
	{
	"Duplicate switch cases (int).",
	`func f(x int) { switch 0 { case x: case 1: } }`,
	`func _() { f(1) }`,
	`func _() {
	var x int = 1
	switch 0 {
	case x:
	case 1:
	}
	}`,
	},
	{
	"Unique switch cases (varied built-in types).",
	`func f(x int) { switch any(nil) { case x: case int16(1): } }`,
	`func _() { f(2) }`,
	`func _() {
	switch any(nil) {
	case 2:
	case int16(1):
	}
	}`,
	},
	{
	"Duplicate switch cases (varied built-in types).",
	`func f(x int) { switch any(nil) { case x: case int16(1): } }`,
	`func _() { f(1) }`,
	`func _() {
	switch any(nil) {
	case 1:
	case int16(1):
	}
	}`,
	},
	})
	}

	func TestFalconDivision(t *testing.T) {
	runTests(t, []testcase{
	{
	"Division by two.",
	`func f(x, y int) int { return x / y }`,
	`func _() { f(1, 2) }`,
	`func _() { _ = 1 / 2 }`,
	},
	{
	"Division by zero.",
	`func f(x, y int) int { return x / y }`,
	`func _() { f(1, 0) }`,
	`func _() {
	var x, y int = 1, 0
	_ = x / y
	}`,
	},
	{
	"Division by two (statement).",
	`func f(x, y int) { x /= y }`,
	`func _() { f(1, 2) }`,
	`func _() {
	var x int = 1
	x /= 2
	}`,
	},
	{
	"Division by zero (statement).",
	`func f(x, y int) { x /= y }`,
	`func _() { f(1, 0) }`,
	`func _() {
	var x, y int = 1, 0
	x /= y
	}`,
	},
	{
	"Division of minint by two (ok).",
	`func f(x, y int32) { _ = x / y }`,
	`func _() { f(-0x80000000, 2) }`,
	`func _() { _ = int32(-0x80000000) / int32(2) }`,
	},
	{
	"Division of minint by -1 (overflow).",
	`func f(x, y int32) { _ = x / y }`,
	`func _() { f(-0x80000000, -1) }`,
	`func _() {
	var x, y int32 = -0x80000000, -1
	_ = x / y
	}`,
	},
	})
	}

	func TestFalconMinusMinInt(t *testing.T) {
	runTests(t, []testcase{
	{
	"Negation of maxint.",
	`func f(x int32) int32 { return -x }`,
	`func _() { f(0x7fffffff) }`,
	`func _() { _ = -int32(0x7fffffff) }`,
	},
	{
	"Negation of minint.",
	`func f(x int32) int32 { return -x }`,
	`func _() { f(-0x80000000) }`,
	`func _() {
	var x int32 = -0x80000000
	_ = -x
	}`,
	},
	})
	}

	func TestFalconArithmeticOverflow(t *testing.T) {
	runTests(t, []testcase{
	{
	"Addition without overflow.",
	`func f(x, y int32) int32 { return x + y }`,
	`func _() { f(100, 200) }`,
	`func _() { _ = int32(100) + int32(200) }`,
	},
	{
	"Addition with overflow.",
	`func f(x, y int32) int32 { return x + y }`,
	`func _() { f(1<<30, 1<<30) }`,
	`func _() {
	var x, y int32 = 1 << 30, 1 << 30
	_ = x + y
	}`,
	},
	{
	"Conversion in range.",
	`func f(x int) int8 { return int8(x) }`,
	`func _() { f(123) }`,
	`func _() { _ = int8(123) }`,
	},
	{
	"Conversion out of range.",
	`func f(x int) int8 { return int8(x) }`,
	`func _() { f(456) }`,
	`func _() {
	var x int = 456
	_ = int8(x)
	}`,
	},
	})
	}

	func TestFalconComplex(t *testing.T) {
	runTests(t, []testcase{
	{
	"Complex arithmetic (good).",
	`func f(re, im float64, z complex128) byte { return "x"[int(real(complex(re, im)*complex(re, -im)-z))] }`,
	`func _() { f(1, 2, 5+0i) }`,
	`func _() { _ = "x"[int(real(complex(float64(1), float64(2))*complex(float64(1), -float64(2))-(5+0i)))] }`,
	},
	{
	"Complex arithmetic (bad).",
	`func f(re, im float64, z complex128) byte { return "x"[int(real(complex(re, im)*complex(re, -im)-z))] }`,
	`func _() { f(1, 3, 5+0i) }`,
	`func _() {
	var (
	re, im float64 = 1, 3
	z complex128 = 5 + 0i
	)
	_ = "x"[int(real(complex(re, im)*complex(re, -im)-z))]
	}`,
	},
	})
	}
	func TestFalconMisc(t *testing.T) {
	runTests(t, []testcase{
	{
	"Compound constant expression (good).",
	`func f(x, y string, i, j int) byte { return x[i*len(y)+j] }`,
	`func _() { f("abc", "xy", 2, -3) }`,
	`func _() { _ = "abc"[2*len("xy")+-3] }`,
	},
	{
	"Compound constant expression (index out of range).",
	`func f(x, y string, i, j int) byte { return x[i*len(y)+j] }`,
	`func _() { f("abc", "xy", 4, -3) }`,
	`func _() {
	var (
	x, y string = "abc", "xy"
	i, j int = 4, -3
	)
	_ = x[i*len(y)+j]
	}`,
	},
	{
	"Constraints within nested functions (good).",
	`func f(x int) { _ = func() { _ = [1]int{}[x] } }`,
	`func _() { f(0) }`,
	`func _() { _ = func() { _ = [1]int{}[0] } }`,
	},
	{
	"Constraints within nested functions (bad).",
	`func f(x int) { _ = func() { _ = [1]int{}[x] } }`,
	`func _() { f(1) }`,
	`func _() {
	var x int = 1
	_ = func() { _ = [1]int{}[x] }
	}`,
	},
	{
	"Falcon violation rejects only the constant arguments (x, z).",
	`func f(x, y, z string) string { return x[:2] + y + z[:2] }; var b string`,
	`func _() { f("a", b, "c") }`,
	`func _() {
	var x, z string = "a", "c"
	_ = x[:2] + b + z[:2]
	}`,
	},
	})
	}