mirror of
https://github.com/go-sylixos/elvish.git
synced 2024-12-05 03:17:50 +08:00
ddf9bf040e
Using a read-only variable as the target of an `except` clause should highlight just the var name rather than the entire `try...except...` statement. Resolves #1258
745 lines
19 KiB
Go
745 lines
19 KiB
Go
package eval
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// Builtin special forms. Special forms behave mostly like ordinary commands -
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// they are valid commands syntactically, and can take part in pipelines - but
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// they have special rules for the evaluation of their arguments and can affect
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// the compilation phase (whereas ordinary commands can only affect the
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// evaluation phase).
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//
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// For example, the "and" special form evaluates its arguments from left to
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// right, and stops as soon as one booleanly false value is obtained: the
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// command "and $false (fail haha)" does not produce an exception.
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//
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// As another example, the "del" special form removes a variable, affecting the
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// compiler.
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//
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// Flow control structures are also implemented as special forms in elvish, with
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// closures functioning as code blocks.
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import (
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"os"
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"path/filepath"
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"strings"
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"src.elv.sh/pkg/diag"
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"src.elv.sh/pkg/eval/mods/bundled"
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"src.elv.sh/pkg/eval/vals"
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"src.elv.sh/pkg/eval/vars"
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"src.elv.sh/pkg/parse"
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"src.elv.sh/pkg/parse/cmpd"
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)
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type compileBuiltin func(*compiler, *parse.Form) effectOp
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var builtinSpecials map[string]compileBuiltin
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// IsBuiltinSpecial is the set of all names of builtin special forms. It is
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// intended for external consumption, e.g. the syntax highlighter.
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var IsBuiltinSpecial = map[string]bool{}
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type noSuchModule struct{ spec string }
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func (err noSuchModule) Error() string { return "no such module: " + err.spec }
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func init() {
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// Needed to avoid initialization loop
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builtinSpecials = map[string]compileBuiltin{
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"var": compileVar,
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"set": compileSet,
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"del": compileDel,
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"fn": compileFn,
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"use": compileUse,
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"and": compileAnd,
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"or": compileOr,
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"if": compileIf,
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"while": compileWhile,
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"for": compileFor,
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"try": compileTry,
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}
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for name := range builtinSpecials {
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IsBuiltinSpecial[name] = true
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}
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}
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// VarForm = 'var' { VariablePrimary } [ '=' { Compound } ]
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func compileVar(cp *compiler, fn *parse.Form) effectOp {
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lhs := lvaluesGroup{rest: -1}
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for i, cn := range fn.Args {
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if parse.SourceText(cn) == "=" {
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var rhs valuesOp
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if i == len(fn.Args)-1 {
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rhs = nopValuesOp{diag.PointRanging(fn.Range().To)}
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} else {
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rhs = seqValuesOp{
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diag.MixedRanging(fn.Args[i+1], fn.Args[len(fn.Args)-1]),
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cp.compoundOps(fn.Args[i+1:])}
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}
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return &assignOp{fn.Range(), lhs, rhs}
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}
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if len(cn.Indexings) != 1 {
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cp.errorpf(cn, "variable name must be a single string literal")
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}
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if len(cn.Indexings[0].Indicies) > 0 {
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cp.errorpf(cn, "variable name must not have indicies")
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}
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pn := cn.Indexings[0].Head
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if !parse.ValidLHSVariable(pn, true) {
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cp.errorpf(cn, "invalid variable name")
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}
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name := pn.Value
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if !IsUnqualified(name) {
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cp.errorpf(cn, "variable declared in var must be unqualified")
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}
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sigil, name := SplitSigil(name)
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if sigil == "@" {
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if lhs.rest != -1 {
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cp.errorpf(cn, "multiple variable names with @ not allowed")
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}
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lhs.rest = i
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}
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slotIndex := cp.thisScope().add(name)
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lhs.lvalues = append(lhs.lvalues,
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lvalue{cn.Range(), &varRef{localScope, slotIndex, nil}, nil, nil})
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}
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// If there is no assignment, there is no work to be done at eval-time.
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return nopOp{}
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}
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// IsUnqualified returns whether name is an unqualified variable name.
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func IsUnqualified(name string) bool {
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i := strings.IndexByte(name, ':')
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return i == -1 || i == len(name)-1
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}
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// SetForm = 'set' { LHS } '=' { Compound }
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func compileSet(cp *compiler, fn *parse.Form) effectOp {
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eq := -1
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for i, cn := range fn.Args {
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if parse.SourceText(cn) == "=" {
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eq = i
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break
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}
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}
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if eq == -1 {
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cp.errorpf(diag.PointRanging(fn.Range().To), "need = and right-hand-side")
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}
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lhs := cp.parseCompoundLValues(fn.Args[:eq])
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var rhs valuesOp
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if eq == len(fn.Args)-1 {
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rhs = nopValuesOp{diag.PointRanging(fn.Range().To)}
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} else {
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rhs = seqValuesOp{
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diag.MixedRanging(fn.Args[eq+1], fn.Args[len(fn.Args)-1]),
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cp.compoundOps(fn.Args[eq+1:])}
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}
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return &assignOp{fn.Range(), lhs, rhs}
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}
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const delArgMsg = "arguments to del must be variable or variable elements"
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// DelForm = 'del' { LHS }
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func compileDel(cp *compiler, fn *parse.Form) effectOp {
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var ops []effectOp
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for _, cn := range fn.Args {
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if len(cn.Indexings) != 1 {
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cp.errorpf(cn, delArgMsg)
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continue
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}
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head, indices := cn.Indexings[0].Head, cn.Indexings[0].Indicies
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if head.Type == parse.Variable {
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cp.errorpf(cn, "arguments to del must drop $")
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} else if !parse.ValidLHSVariable(head, false) {
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cp.errorpf(cn, delArgMsg)
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}
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qname := head.Value
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var f effectOp
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ref := resolveVarRef(cp, qname, nil)
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if ref == nil {
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cp.errorpf(cn, "no variable $%s", head.Value)
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continue
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}
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if len(indices) == 0 {
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if ref.scope == envScope {
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f = delEnvVarOp{fn.Range(), ref.subNames[0]}
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} else if ref.scope == localScope && len(ref.subNames) == 0 {
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f = delLocalVarOp{ref.index}
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cp.thisScope().deleted[ref.index] = true
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} else {
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cp.errorpf(cn, "only variables in local: or E: can be deleted")
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continue
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}
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} else {
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f = newDelElementOp(ref, head.Range().From, head.Range().To, cp.arrayOps(indices))
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}
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ops = append(ops, f)
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}
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return seqOp{ops}
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}
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type delLocalVarOp struct{ index int }
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func (op delLocalVarOp) exec(fm *Frame) Exception {
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fm.local.slots[op.index] = nil
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return nil
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}
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type delEnvVarOp struct {
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diag.Ranging
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name string
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}
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func (op delEnvVarOp) exec(fm *Frame) Exception {
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return fm.errorp(op, os.Unsetenv(op.name))
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}
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func newDelElementOp(ref *varRef, begin, headEnd int, indexOps []valuesOp) effectOp {
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ends := make([]int, len(indexOps)+1)
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ends[0] = headEnd
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for i, op := range indexOps {
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ends[i+1] = op.Range().To
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}
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return &delElemOp{ref, indexOps, begin, ends}
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}
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type delElemOp struct {
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ref *varRef
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indexOps []valuesOp
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begin int
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ends []int
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}
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func (op *delElemOp) Range() diag.Ranging {
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return diag.Ranging{From: op.begin, To: op.ends[0]}
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}
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func (op *delElemOp) exec(fm *Frame) Exception {
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var indices []interface{}
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for _, indexOp := range op.indexOps {
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indexValues, exc := indexOp.exec(fm)
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if exc != nil {
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return exc
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}
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if len(indexValues) != 1 {
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return fm.errorpf(indexOp, "index must evaluate to a single value in argument to del")
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}
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indices = append(indices, indexValues[0])
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}
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err := vars.DelElement(deref(fm, op.ref), indices)
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if err != nil {
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if level := vars.ElementErrorLevel(err); level >= 0 {
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return fm.errorp(diag.Ranging{From: op.begin, To: op.ends[level]}, err)
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}
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return fm.errorp(op, err)
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}
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return nil
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}
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// FnForm = 'fn' StringPrimary LambdaPrimary
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//
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// fn f []{foobar} is a shorthand for set '&'f = []{foobar}.
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func compileFn(cp *compiler, fn *parse.Form) effectOp {
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args := cp.walkArgs(fn)
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nameNode := args.next()
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name := stringLiteralOrError(cp, nameNode, "function name")
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bodyNode := args.nextMustLambda("function body")
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args.mustEnd()
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// Define the variable before compiling the body, so that the body may refer
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// to the function itself.
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index := cp.thisScope().add(name + FnSuffix)
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op := cp.lambda(bodyNode)
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return fnOp{nameNode.Range(), index, op}
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}
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type fnOp struct {
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keywordRange diag.Ranging
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varIndex int
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lambdaOp valuesOp
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}
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func (op fnOp) exec(fm *Frame) Exception {
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// Initialize the function variable with the builtin nop function. This step
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// allows the definition of recursive functions; the actual function will
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// never be called.
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fm.local.slots[op.varIndex].Set(NewGoFn("<shouldn't be called>", nop))
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values, exc := op.lambdaOp.exec(fm)
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if exc != nil {
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return exc
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}
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c := values[0].(*closure)
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c.Op = fnWrap{c.Op}
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return fm.errorp(op.keywordRange, fm.local.slots[op.varIndex].Set(c))
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}
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type fnWrap struct{ effectOp }
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func (op fnWrap) Range() diag.Ranging { return op.effectOp.(diag.Ranger).Range() }
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func (op fnWrap) exec(fm *Frame) Exception {
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exc := op.effectOp.exec(fm)
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if exc != nil && exc.Reason() != Return {
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// rethrow
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return exc
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}
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return nil
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}
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// UseForm = 'use' StringPrimary
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func compileUse(cp *compiler, fn *parse.Form) effectOp {
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var name, spec string
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switch len(fn.Args) {
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case 0:
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end := fn.Head.Range().To
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cp.errorpf(diag.PointRanging(end), "lack module name")
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case 1:
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spec = stringLiteralOrError(cp, fn.Args[0], "module spec")
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// Use the last path component as the name; for instance, if path =
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// "a/b/c/d", name is "d". If path doesn't have slashes, name = path.
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name = spec[strings.LastIndexByte(spec, '/')+1:]
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case 2:
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// TODO(xiaq): Allow using variable as module path
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spec = stringLiteralOrError(cp, fn.Args[0], "module spec")
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name = stringLiteralOrError(cp, fn.Args[1], "module name")
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default: // > 2
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cp.errorpf(diag.MixedRanging(fn.Args[2], fn.Args[len(fn.Args)-1]),
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"superfluous argument(s)")
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}
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return useOp{fn.Range(), cp.thisScope().add(name + NsSuffix), spec}
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}
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type useOp struct {
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diag.Ranging
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varIndex int
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spec string
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}
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func (op useOp) exec(fm *Frame) Exception {
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ns, err := use(fm, op.spec, op)
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if err != nil {
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return fm.errorp(op, err)
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}
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fm.local.slots[op.varIndex].Set(ns)
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return nil
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}
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var bundledModules = bundled.Get()
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func use(fm *Frame, spec string, r diag.Ranger) (*Ns, error) {
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if strings.HasPrefix(spec, "./") || strings.HasPrefix(spec, "../") {
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var dir string
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if fm.srcMeta.IsFile {
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dir = filepath.Dir(fm.srcMeta.Name)
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} else {
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var err error
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dir, err = os.Getwd()
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if err != nil {
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return nil, err
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}
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}
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path := filepath.Clean(dir + "/" + spec + ".elv")
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return useFromFile(fm, spec, path, r)
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}
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if ns, ok := fm.Evaler.modules[spec]; ok {
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return ns, nil
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}
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if code, ok := bundledModules[spec]; ok {
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return evalModule(fm, spec,
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parse.Source{Name: "[bundled " + spec + "]", Code: code}, r)
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}
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libDir := fm.Evaler.getLibDir()
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if libDir == "" {
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return nil, noSuchModule{spec}
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}
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return useFromFile(fm, spec, libDir+"/"+spec+".elv", r)
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}
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// TODO: Make access to fm.Evaler.modules concurrency-safe.
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func useFromFile(fm *Frame, spec, path string, r diag.Ranger) (*Ns, error) {
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if ns, ok := fm.Evaler.modules[path]; ok {
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return ns, nil
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}
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code, err := readFileUTF8(path)
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if err != nil {
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if os.IsNotExist(err) {
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return nil, noSuchModule{spec}
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}
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return nil, err
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}
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return evalModule(fm, path, parse.Source{Name: path, Code: code, IsFile: true}, r)
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}
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// TODO: Make access to fm.Evaler.modules concurrency-safe.
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func evalModule(fm *Frame, key string, src parse.Source, r diag.Ranger) (*Ns, error) {
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ns, exec, err := fm.PrepareEval(src, r, new(Ns))
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if err != nil {
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return nil, err
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}
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// Installs the namespace before executing. This prevent circular use'es
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// from resulting in an infinite recursion.
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fm.Evaler.modules[key] = ns
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err = exec()
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if err != nil {
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// Unload the namespace.
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delete(fm.Evaler.modules, key)
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return nil, err
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}
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return ns, nil
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}
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// compileAnd compiles the "and" special form.
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//
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// The and special form evaluates arguments until a false-ish values is found
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// and outputs it; the remaining arguments are not evaluated. If there are no
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// false-ish values, the last value is output. If there are no arguments, it
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// outputs $true, as if there is a hidden $true before actual arguments.
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func compileAnd(cp *compiler, fn *parse.Form) effectOp {
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return &andOrOp{cp.compoundOps(fn.Args), true, false}
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}
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// compileOr compiles the "or" special form.
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//
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// The or special form evaluates arguments until a true-ish values is found and
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// outputs it; the remaining arguments are not evaluated. If there are no
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// true-ish values, the last value is output. If there are no arguments, it
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// outputs $false, as if there is a hidden $false before actual arguments.
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func compileOr(cp *compiler, fn *parse.Form) effectOp {
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return &andOrOp{cp.compoundOps(fn.Args), false, true}
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}
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type andOrOp struct {
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argOps []valuesOp
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init bool
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stopAt bool
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}
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func (op *andOrOp) exec(fm *Frame) Exception {
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var lastValue interface{} = vals.Bool(op.init)
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for _, argOp := range op.argOps {
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values, exc := argOp.exec(fm)
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if exc != nil {
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return exc
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}
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for _, value := range values {
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if vals.Bool(value) == op.stopAt {
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fm.OutputChan() <- value
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return nil
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}
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lastValue = value
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}
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}
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fm.OutputChan() <- lastValue
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return nil
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}
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func compileIf(cp *compiler, fn *parse.Form) effectOp {
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args := cp.walkArgs(fn)
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var condNodes []*parse.Compound
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var bodyNodes []*parse.Primary
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condLeader := "if"
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for {
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condNodes = append(condNodes, args.next())
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bodyNodes = append(bodyNodes, args.nextMustLambda(condLeader))
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if !args.nextIs("elif") {
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break
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}
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condLeader = "elif"
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}
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elseNode := args.nextMustLambdaIfAfter("else")
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args.mustEnd()
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condOps := cp.compoundOps(condNodes)
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bodyOps := cp.primaryOps(bodyNodes)
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var elseOp valuesOp
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if elseNode != nil {
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elseOp = cp.primaryOp(elseNode)
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}
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return &ifOp{fn.Range(), condOps, bodyOps, elseOp}
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}
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type ifOp struct {
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diag.Ranging
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condOps []valuesOp
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bodyOps []valuesOp
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elseOp valuesOp
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}
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func (op *ifOp) exec(fm *Frame) Exception {
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bodies := make([]Callable, len(op.bodyOps))
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for i, bodyOp := range op.bodyOps {
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bodies[i] = execLambdaOp(fm, bodyOp)
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}
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elseFn := execLambdaOp(fm, op.elseOp)
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for i, condOp := range op.condOps {
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condValues, exc := condOp.exec(fm.fork("if cond"))
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if exc != nil {
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return exc
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}
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if allTrue(condValues) {
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return fm.errorp(op, bodies[i].Call(fm.fork("if body"), NoArgs, NoOpts))
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}
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}
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if op.elseOp != nil {
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return fm.errorp(op, elseFn.Call(fm.fork("if else"), NoArgs, NoOpts))
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}
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return nil
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}
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func compileWhile(cp *compiler, fn *parse.Form) effectOp {
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args := cp.walkArgs(fn)
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condNode := args.next()
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bodyNode := args.nextMustLambda("while body")
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elseNode := args.nextMustLambdaIfAfter("else")
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args.mustEnd()
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condOp := cp.compoundOp(condNode)
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bodyOp := cp.primaryOp(bodyNode)
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var elseOp valuesOp
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if elseNode != nil {
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elseOp = cp.primaryOp(elseNode)
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}
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return &whileOp{fn.Range(), condOp, bodyOp, elseOp}
|
|
}
|
|
|
|
type whileOp struct {
|
|
diag.Ranging
|
|
condOp, bodyOp, elseOp valuesOp
|
|
}
|
|
|
|
func (op *whileOp) exec(fm *Frame) Exception {
|
|
body := execLambdaOp(fm, op.bodyOp)
|
|
elseBody := execLambdaOp(fm, op.elseOp)
|
|
|
|
iterated := false
|
|
for {
|
|
condValues, exc := op.condOp.exec(fm.fork("while cond"))
|
|
if exc != nil {
|
|
return exc
|
|
}
|
|
if !allTrue(condValues) {
|
|
break
|
|
}
|
|
iterated = true
|
|
err := body.Call(fm.fork("while"), NoArgs, NoOpts)
|
|
if err != nil {
|
|
exc := err.(Exception)
|
|
if exc.Reason() == Continue {
|
|
// Do nothing
|
|
} else if exc.Reason() == Break {
|
|
break
|
|
} else {
|
|
return exc
|
|
}
|
|
}
|
|
}
|
|
|
|
if op.elseOp != nil && !iterated {
|
|
return fm.errorp(op, elseBody.Call(fm.fork("while else"), NoArgs, NoOpts))
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func compileFor(cp *compiler, fn *parse.Form) effectOp {
|
|
args := cp.walkArgs(fn)
|
|
varNode := args.next()
|
|
iterNode := args.next()
|
|
bodyNode := args.nextMustLambda("for body")
|
|
elseNode := args.nextMustLambdaIfAfter("else")
|
|
args.mustEnd()
|
|
|
|
lvalue := cp.compileOneLValue(varNode)
|
|
|
|
iterOp := cp.compoundOp(iterNode)
|
|
bodyOp := cp.primaryOp(bodyNode)
|
|
var elseOp valuesOp
|
|
if elseNode != nil {
|
|
elseOp = cp.primaryOp(elseNode)
|
|
}
|
|
|
|
return &forOp{fn.Range(), lvalue, iterOp, bodyOp, elseOp}
|
|
}
|
|
|
|
type forOp struct {
|
|
diag.Ranging
|
|
lvalue lvalue
|
|
iterOp valuesOp
|
|
bodyOp valuesOp
|
|
elseOp valuesOp
|
|
}
|
|
|
|
func (op *forOp) exec(fm *Frame) Exception {
|
|
variable, err := derefLValue(fm, op.lvalue)
|
|
if err != nil {
|
|
return fm.errorp(op, err)
|
|
}
|
|
iterable, err := evalForValue(fm, op.iterOp, "value being iterated")
|
|
if err != nil {
|
|
return fm.errorp(op, err)
|
|
}
|
|
|
|
body := execLambdaOp(fm, op.bodyOp)
|
|
elseBody := execLambdaOp(fm, op.elseOp)
|
|
|
|
iterated := false
|
|
var errElement error
|
|
errIterate := vals.Iterate(iterable, func(v interface{}) bool {
|
|
iterated = true
|
|
err := variable.Set(v)
|
|
if err != nil {
|
|
errElement = err
|
|
return false
|
|
}
|
|
err = body.Call(fm.fork("for"), NoArgs, NoOpts)
|
|
if err != nil {
|
|
exc := err.(Exception)
|
|
if exc.Reason() == Continue {
|
|
// do nothing
|
|
} else if exc.Reason() == Break {
|
|
return false
|
|
} else {
|
|
errElement = err
|
|
return false
|
|
}
|
|
}
|
|
return true
|
|
})
|
|
if errIterate != nil {
|
|
return fm.errorp(op, errIterate)
|
|
}
|
|
if errElement != nil {
|
|
return fm.errorp(op, errElement)
|
|
}
|
|
|
|
if !iterated && elseBody != nil {
|
|
return fm.errorp(op, elseBody.Call(fm.fork("for else"), NoArgs, NoOpts))
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func compileTry(cp *compiler, fn *parse.Form) effectOp {
|
|
logger.Println("compiling try")
|
|
args := cp.walkArgs(fn)
|
|
bodyNode := args.nextMustLambda("try body")
|
|
logger.Printf("body is %q", parse.SourceText(bodyNode))
|
|
var exceptVarNode *parse.Compound
|
|
var exceptNode *parse.Primary
|
|
if args.nextIs("except") {
|
|
logger.Println("except-ing")
|
|
// Parse an optional lvalue into exceptVarNode.
|
|
n := args.peek()
|
|
if _, ok := cmpd.StringLiteral(n); ok {
|
|
exceptVarNode = n
|
|
args.next()
|
|
}
|
|
exceptNode = args.nextMustLambda("except body")
|
|
}
|
|
elseNode := args.nextMustLambdaIfAfter("else")
|
|
finallyNode := args.nextMustLambdaIfAfter("finally")
|
|
args.mustEnd()
|
|
|
|
var exceptVar lvalue
|
|
var bodyOp, exceptOp, elseOp, finallyOp valuesOp
|
|
bodyOp = cp.primaryOp(bodyNode)
|
|
if exceptVarNode != nil {
|
|
exceptVar = cp.compileOneLValue(exceptVarNode)
|
|
}
|
|
if exceptNode != nil {
|
|
exceptOp = cp.primaryOp(exceptNode)
|
|
}
|
|
if elseNode != nil {
|
|
elseOp = cp.primaryOp(elseNode)
|
|
}
|
|
if finallyNode != nil {
|
|
finallyOp = cp.primaryOp(finallyNode)
|
|
}
|
|
|
|
return &tryOp{fn.Range(), bodyOp, exceptVar, exceptOp, elseOp, finallyOp}
|
|
}
|
|
|
|
type tryOp struct {
|
|
diag.Ranging
|
|
bodyOp valuesOp
|
|
exceptVar lvalue
|
|
exceptOp valuesOp
|
|
elseOp valuesOp
|
|
finallyOp valuesOp
|
|
}
|
|
|
|
func (op *tryOp) exec(fm *Frame) Exception {
|
|
body := execLambdaOp(fm, op.bodyOp)
|
|
var exceptVar vars.Var
|
|
if op.exceptVar.ref != nil {
|
|
var err error
|
|
exceptVar, err = derefLValue(fm, op.exceptVar)
|
|
if err != nil {
|
|
return fm.errorp(op, err)
|
|
}
|
|
}
|
|
except := execLambdaOp(fm, op.exceptOp)
|
|
elseFn := execLambdaOp(fm, op.elseOp)
|
|
finally := execLambdaOp(fm, op.finallyOp)
|
|
|
|
err := body.Call(fm.fork("try body"), NoArgs, NoOpts)
|
|
if err != nil {
|
|
if except != nil {
|
|
if exceptVar != nil {
|
|
err := exceptVar.Set(err.(Exception))
|
|
if err != nil {
|
|
return fm.errorp(op.exceptVar, err)
|
|
}
|
|
}
|
|
err = except.Call(fm.fork("try except"), NoArgs, NoOpts)
|
|
}
|
|
} else {
|
|
if elseFn != nil {
|
|
err = elseFn.Call(fm.fork("try else"), NoArgs, NoOpts)
|
|
}
|
|
}
|
|
if finally != nil {
|
|
errFinally := finally.Call(fm.fork("try finally"), NoArgs, NoOpts)
|
|
if errFinally != nil {
|
|
// TODO: If err is not nil, this discards err. Use something similar
|
|
// to pipeline exception to expose both.
|
|
return fm.errorp(op, errFinally)
|
|
}
|
|
}
|
|
return fm.errorp(op, err)
|
|
}
|
|
|
|
func (cp *compiler) compileOneLValue(n *parse.Compound) lvalue {
|
|
if len(n.Indexings) != 1 {
|
|
cp.errorpf(n, "must be valid lvalue")
|
|
}
|
|
lvalues := cp.parseIndexingLValue(n.Indexings[0])
|
|
if lvalues.rest != -1 {
|
|
cp.errorpf(lvalues.lvalues[lvalues.rest], "rest variable not allowed")
|
|
}
|
|
if len(lvalues.lvalues) != 1 {
|
|
cp.errorpf(n, "must be exactly one lvalue")
|
|
}
|
|
return lvalues.lvalues[0]
|
|
}
|
|
|
|
// Executes a valuesOp that is known to yield a lambda and returns the lambda.
|
|
// Returns nil if op is nil.
|
|
func execLambdaOp(fm *Frame, op valuesOp) Callable {
|
|
if op == nil {
|
|
return nil
|
|
}
|
|
values, exc := op.exec(fm)
|
|
if exc != nil {
|
|
panic("must not be erroneous")
|
|
}
|
|
return values[0].(Callable)
|
|
}
|