package eval import ( "fmt" "math" "math/big" "math/rand" "strconv" "time" "src.elv.sh/pkg/eval/errs" "src.elv.sh/pkg/eval/vals" ) // Numerical operations. func init() { addBuiltinFns(map[string]any{ // Constructor "num": num, "exact-num": exactNum, "inexact-num": inexactNum, // Comparison "<": lt, "<=": le, "==": eqNum, "!=": ne, ">": gt, ">=": ge, // Arithmetic "+": add, "-": sub, "*": mul, // Also handles cd / "/": slash, "%": rem, // Random "rand": rand.Float64, "randint": randint, "-randseed": randseed, "range": rangeFn, }) // For rand and randint. rand.Seed(time.Now().UTC().UnixNano()) } func num(n vals.Num) vals.Num { // Conversion is actually handled in vals/conversion.go. return n } func exactNum(n vals.Num) (vals.Num, error) { if f, ok := n.(float64); ok { r := new(big.Rat).SetFloat64(f) if r == nil { return nil, errs.BadValue{What: "argument here", Valid: "finite float", Actual: vals.ToString(f)} } return r, nil } return n, nil } func inexactNum(f float64) float64 { return f } func lt(nums ...vals.Num) bool { return chainCompare(nums, func(a, b int) bool { return a < b }, func(a, b *big.Int) bool { return a.Cmp(b) < 0 }, func(a, b *big.Rat) bool { return a.Cmp(b) < 0 }, func(a, b float64) bool { return a < b }) } func le(nums ...vals.Num) bool { return chainCompare(nums, func(a, b int) bool { return a <= b }, func(a, b *big.Int) bool { return a.Cmp(b) <= 0 }, func(a, b *big.Rat) bool { return a.Cmp(b) <= 0 }, func(a, b float64) bool { return a <= b }) } func eqNum(nums ...vals.Num) bool { return chainCompare(nums, func(a, b int) bool { return a == b }, func(a, b *big.Int) bool { return a.Cmp(b) == 0 }, func(a, b *big.Rat) bool { return a.Cmp(b) == 0 }, func(a, b float64) bool { return a == b }) } func ne(nums ...vals.Num) bool { return chainCompare(nums, func(a, b int) bool { return a != b }, func(a, b *big.Int) bool { return a.Cmp(b) != 0 }, func(a, b *big.Rat) bool { return a.Cmp(b) != 0 }, func(a, b float64) bool { return a != b }) } func gt(nums ...vals.Num) bool { return chainCompare(nums, func(a, b int) bool { return a > b }, func(a, b *big.Int) bool { return a.Cmp(b) > 0 }, func(a, b *big.Rat) bool { return a.Cmp(b) > 0 }, func(a, b float64) bool { return a > b }) } func ge(nums ...vals.Num) bool { return chainCompare(nums, func(a, b int) bool { return a >= b }, func(a, b *big.Int) bool { return a.Cmp(b) >= 0 }, func(a, b *big.Rat) bool { return a.Cmp(b) >= 0 }, func(a, b float64) bool { return a >= b }) } func chainCompare(nums []vals.Num, p1 func(a, b int) bool, p2 func(a, b *big.Int) bool, p3 func(a, b *big.Rat) bool, p4 func(a, b float64) bool) bool { for i := 0; i < len(nums)-1; i++ { var r bool a, b := vals.UnifyNums2(nums[i], nums[i+1], 0) switch a := a.(type) { case int: r = p1(a, b.(int)) case *big.Int: r = p2(a, b.(*big.Int)) case *big.Rat: r = p3(a, b.(*big.Rat)) case float64: r = p4(a, b.(float64)) } if !r { return false } } return true } func add(rawNums ...vals.Num) vals.Num { nums := vals.UnifyNums(rawNums, vals.BigInt) switch nums := nums.(type) { case []*big.Int: acc := big.NewInt(0) for _, num := range nums { acc.Add(acc, num) } return vals.NormalizeBigInt(acc) case []*big.Rat: acc := big.NewRat(0, 1) for _, num := range nums { acc.Add(acc, num) } return vals.NormalizeBigRat(acc) case []float64: acc := float64(0) for _, num := range nums { acc += num } return acc default: panic("unreachable") } } func sub(rawNums ...vals.Num) (vals.Num, error) { if len(rawNums) == 0 { return nil, errs.ArityMismatch{What: "arguments", ValidLow: 1, ValidHigh: -1, Actual: 0} } nums := vals.UnifyNums(rawNums, vals.BigInt) switch nums := nums.(type) { case []*big.Int: acc := &big.Int{} if len(nums) == 1 { acc.Neg(nums[0]) return acc, nil } acc.Set(nums[0]) for _, num := range nums[1:] { acc.Sub(acc, num) } return acc, nil case []*big.Rat: acc := &big.Rat{} if len(nums) == 1 { acc.Neg(nums[0]) return acc, nil } acc.Set(nums[0]) for _, num := range nums[1:] { acc.Sub(acc, num) } return acc, nil case []float64: if len(nums) == 1 { return -nums[0], nil } acc := nums[0] for _, num := range nums[1:] { acc -= num } return acc, nil default: panic("unreachable") } } func mul(rawNums ...vals.Num) vals.Num { hasExact0 := false hasInf := false for _, num := range rawNums { if num == 0 { hasExact0 = true } if f, ok := num.(float64); ok && math.IsInf(f, 0) { hasInf = true break } } if hasExact0 && !hasInf { return 0 } nums := vals.UnifyNums(rawNums, vals.BigInt) switch nums := nums.(type) { case []*big.Int: acc := big.NewInt(1) for _, num := range nums { acc.Mul(acc, num) } return vals.NormalizeBigInt(acc) case []*big.Rat: acc := big.NewRat(1, 1) for _, num := range nums { acc.Mul(acc, num) } return vals.NormalizeBigRat(acc) case []float64: acc := float64(1) for _, num := range nums { acc *= num } return acc default: panic("unreachable") } } func slash(fm *Frame, args ...vals.Num) error { if len(args) == 0 { // cd / return fm.Evaler.Chdir("/") } // Division result, err := div(args...) if err != nil { return err } return fm.ValueOutput().Put(vals.FromGo(result)) } // ErrDivideByZero is thrown when attempting to divide by zero. var ErrDivideByZero = errs.BadValue{ What: "divisor", Valid: "number other than exact 0", Actual: "exact 0"} func div(rawNums ...vals.Num) (vals.Num, error) { for _, num := range rawNums[1:] { if num == 0 { return nil, ErrDivideByZero } } if rawNums[0] == 0 { return 0, nil } nums := vals.UnifyNums(rawNums, vals.BigRat) switch nums := nums.(type) { case []*big.Rat: acc := &big.Rat{} acc.Set(nums[0]) if len(nums) == 1 { acc.Inv(acc) return acc, nil } for _, num := range nums[1:] { acc.Quo(acc, num) } return acc, nil case []float64: acc := nums[0] if len(nums) == 1 { return 1 / acc, nil } for _, num := range nums[1:] { acc /= num } return acc, nil default: panic("unreachable") } } func rem(a, b int) (int, error) { // TODO: Support other number types if b == 0 { return 0, ErrDivideByZero } return a % b, nil } func randint(args ...int) (int, error) { var low, high int switch len(args) { case 1: low, high = 0, args[0] case 2: low, high = args[0], args[1] default: return -1, errs.ArityMismatch{What: "arguments", ValidLow: 1, ValidHigh: 2, Actual: len(args)} } if high <= low { return 0, errs.BadValue{What: "high value", Valid: fmt.Sprint("larger than ", low), Actual: strconv.Itoa(high)} } return low + rand.Intn(high-low), nil } func randseed(x int) { rand.Seed(int64(x)) } type rangeOpts struct{ Step vals.Num } // TODO: The default value can only be used implicitly; passing "range // &step=nil" results in an error. func (o *rangeOpts) SetDefaultOptions() { o.Step = nil } func rangeFn(fm *Frame, opts rangeOpts, args ...vals.Num) error { var rawNums []vals.Num switch len(args) { case 1: rawNums = []vals.Num{0, args[0]} case 2: rawNums = []vals.Num{args[0], args[1]} default: return errs.ArityMismatch{What: "arguments", ValidLow: 1, ValidHigh: 2, Actual: len(args)} } if opts.Step != nil { rawNums = append(rawNums, opts.Step) } nums := vals.UnifyNums(rawNums, vals.Int) out := fm.ValueOutput() switch nums := nums.(type) { case []int: return rangeBuiltinNum(nums, out) case []*big.Int: return rangeBigNum(nums, out, bigIntDesc) case []*big.Rat: return rangeBigNum(nums, out, bigRatDesc) case []float64: return rangeBuiltinNum(nums, out) default: panic("unreachable") } } type builtinNum interface{ int | float64 } func rangeBuiltinNum[T builtinNum](nums []T, out ValueOutput) error { start, end := nums[0], nums[1] var step T if start <= end { if len(nums) == 3 { step = nums[2] if step <= 0 { return errs.BadValue{ What: "step", Valid: "positive", Actual: vals.ToString(step)} } } else { step = 1 } for cur := start; cur < end; cur += step { err := out.Put(vals.FromGo(cur)) if err != nil { return err } if cur+step <= cur { break } } } else { if len(nums) == 3 { step = nums[2] if step >= 0 { return errs.BadValue{ What: "step", Valid: "negative", Actual: vals.ToString(step)} } } else { step = -1 } for cur := start; cur > end; cur += step { err := out.Put(vals.FromGo(cur)) if err != nil { return err } if cur+step >= cur { break } } } return nil } type bigNum[T any] interface { Cmp(T) int Sign() int Add(T, T) T } type bigNumDesc[T any] struct { one T negOne T newZero func() T } var bigIntDesc = bigNumDesc[*big.Int]{ one: big.NewInt(1), negOne: big.NewInt(-1), newZero: func() *big.Int { return &big.Int{} }, } var bigRatDesc = bigNumDesc[*big.Rat]{ one: big.NewRat(1, 1), negOne: big.NewRat(-1, 1), newZero: func() *big.Rat { return &big.Rat{} }, } func rangeBigNum[T bigNum[T]](nums []T, out ValueOutput, d bigNumDesc[T]) error { start, end := nums[0], nums[1] var step T if start.Cmp(end) <= 0 { if len(nums) == 3 { step = nums[2] if step.Sign() <= 0 { return errs.BadValue{ What: "step", Valid: "positive", Actual: vals.ToString(step)} } } else { step = d.one } var cur, next T for cur = start; cur.Cmp(end) < 0; cur = next { err := out.Put(vals.FromGo(cur)) if err != nil { return err } next = d.newZero() next.Add(cur, step) cur = next } } else { if len(nums) == 3 { step = nums[2] if step.Sign() >= 0 { return errs.BadValue{ What: "step", Valid: "negative", Actual: vals.ToString(step)} } } else { step = d.negOne } var cur, next T for cur = start; cur.Cmp(end) > 0; cur = next { err := out.Put(vals.FromGo(cur)) if err != nil { return err } next = d.newZero() next.Add(cur, step) cur = next } } return nil }