Google Git
Sign in
android / platform / external / starlark-go / 551f300 / . / internal / compile / compile.go
blob: 99e9d542dfbf570ae93e6f88f33e3e87da31be90 [file] [log] [blame]
// The compile package defines the Starlark bytecode compiler.
// It is an internal package of the Starlark interpreter and is not directly accessible to clients.
//
// The compiler generates byte code with optional uint32 operands for a
// virtual machine with the following components:
// - a program counter, which is an index into the byte code array.
// - an operand stack, whose maximum size is computed for each function by the compiler.
// - an stack of active iterators.
// - an array of local variables.
// The number of local variables and their indices are computed by the resolver.
// - an array of free variables, for nested functions.
// As with locals, these are computed by the resolver.
// - an array of global variables, shared among all functions in the same module.
// All elements are initially nil.
// - two maps of predeclared and universal identifiers.
//
// A line number table maps each program counter value to a source position;
// these source positions do not currently record column information.
//
// Operands, logically uint32s, are encoded using little-endian 7-bit
// varints, the top bit indicating that more bytes follow.
//
package compile // import "go.starlark.net/internal/compile"
import (
"bytes"
"fmt"
"log"
"os"
"path/filepath"
"strconv"
"go.starlark.net/resolve"
"go.starlark.net/syntax"
)
const debug = false // TODO(adonovan): use a bitmap of options; and regexp to match files
// Increment this to force recompilation of saved bytecode files.
const Version = 3
type Opcode uint8
// "x DUP x x" is a "stack picture" that describes the state of the
// stack before and after execution of the instruction.
//
// OP<index> indicates an immediate operand that is an index into the
// specified table: locals, names, freevars, constants.
const (
NOP Opcode = iota // - NOP -
// stack operations
DUP // x DUP x x
DUP2 // x y DUP2 x y x y
POP // x POP -
EXCH // x y EXCH y x
// binary comparisons
// (order must match Token)
LT
GT
GE
LE
EQL
NEQ
// binary arithmetic
// (order must match Token)
PLUS
MINUS
STAR
SLASH
SLASHSLASH
PERCENT
AMP
PIPE
CIRCUMFLEX
LTLT
GTGT
IN
// unary operators
UPLUS // x UPLUS x
UMINUS // x UMINUS -x
TILDE // x TILDE ~x
NONE // - NONE None
TRUE // - TRUE True
FALSE // - FALSE False
ITERPUSH // iterable ITERPUSH - [pushes the iterator stack]
ITERPOP // - ITERPOP - [pops the iterator stack]
NOT // value NOT bool
RETURN // value RETURN -
SETINDEX // a i new SETINDEX -
INDEX // a i INDEX elem
SETDICT // dict key value SETDICT -
SETDICTUNIQ // dict key value SETDICTUNIQ -
APPEND // list elem APPEND -
SLICE // x lo hi step SLICE slice
INPLACE_ADD // x y INPLACE_ADD z where z is x+y or x.extend(y)
MAKEDICT // - MAKEDICT dict
// --- opcodes with an argument must go below this line ---
// control flow
JMP // - JMP<addr> -
CJMP // cond CJMP<addr> -
ITERJMP // - ITERJMP<addr> elem (and fall through) [acts on topmost iterator]
// or: - ITERJMP<addr> - (and jump)
CONSTANT // - CONSTANT<constant> value
MAKETUPLE // x1 ... xn MAKETUPLE<n> tuple
MAKELIST // x1 ... xn MAKELIST<n> list
MAKEFUNC // args kwargs MAKEFUNC<func> fn
LOAD // from1 ... fromN module LOAD<n> v1 ... vN
SETLOCAL // value SETLOCAL<local> -
SETGLOBAL // value SETGLOBAL<global> -
LOCAL // - LOCAL<local> value
FREE // - FREE<freevar> value
GLOBAL // - GLOBAL<global> value
PREDECLARED // - PREDECLARED<name> value
UNIVERSAL // - UNIVERSAL<name> value
ATTR // x ATTR<name> y y = x.name
SETFIELD // x y SETFIELD<name> - x.name = y
UNPACK // iterable UNPACK<n> vn ... v1
// n>>8 is #positional args and n&0xff is #named args (pairs).
CALL // fn positional named CALL<n> result
CALL_VAR // fn positional named *args CALL_VAR<n> result
CALL_KW // fn positional named **kwargs CALL_KW<n> result
CALL_VAR_KW // fn positional named *args **kwargs CALL_VAR_KW<n> result
OpcodeArgMin = JMP
OpcodeMax = CALL_VAR_KW
)
// TODO(adonovan): add dynamic checks for missing opcodes in the tables below.
var opcodeNames = [...]string{
AMP: "amp",
APPEND: "append",
ATTR: "attr",
CALL: "call",
CALL_KW: "call_kw ",
CALL_VAR: "call_var",
CALL_VAR_KW: "call_var_kw",
CIRCUMFLEX: "circumflex",
CJMP: "cjmp",
CONSTANT: "constant",
DUP2: "dup2",
DUP: "dup",
EQL: "eql",
FALSE: "false",
FREE: "free",
GE: "ge",
GLOBAL: "global",
GT: "gt",
GTGT: "gtgt",
IN: "in",
INDEX: "index",
INPLACE_ADD: "inplace_add",
ITERJMP: "iterjmp",
ITERPOP: "iterpop",
ITERPUSH: "iterpush",
JMP: "jmp",
LE: "le",
LOAD: "load",
LOCAL: "local",
LT: "lt",
LTLT: "ltlt",
MAKEDICT: "makedict",
MAKEFUNC: "makefunc",
MAKELIST: "makelist",
MAKETUPLE: "maketuple",
MINUS: "minus",
NEQ: "neq",
NONE: "none",
NOP: "nop",
NOT: "not",
PERCENT: "percent",
PIPE: "pipe",
PLUS: "plus",
POP: "pop",
PREDECLARED: "predeclared",
RETURN: "return",
SETDICT: "setdict",
SETDICTUNIQ: "setdictuniq",
SETFIELD: "setfield",
SETGLOBAL: "setglobal",
SETINDEX: "setindex",
SETLOCAL: "setlocal",
SLASH: "slash",
SLASHSLASH: "slashslash",
SLICE: "slice",
STAR: "star",
TILDE: "tilde",
TRUE: "true",
UMINUS: "uminus",
UNIVERSAL: "universal",
UNPACK: "unpack",
UPLUS: "uplus",
}
const variableStackEffect = 0x7f
// stackEffect records the effect on the size of the operand stack of
// each kind of instruction. For some instructions this requires computation.
var stackEffect = [...]int8{
AMP: -1,
APPEND: -2,
ATTR: 0,
CALL: variableStackEffect,
CALL_KW: variableStackEffect,
CALL_VAR: variableStackEffect,
CALL_VAR_KW: variableStackEffect,
CIRCUMFLEX: -1,
CJMP: -1,
CONSTANT: +1,
DUP2: +2,
DUP: +1,
EQL: -1,
FALSE: +1,
FREE: +1,
GE: -1,
GLOBAL: +1,
GT: -1,
GTGT: -1,
IN: -1,
INDEX: -1,
INPLACE_ADD: -1,
ITERJMP: variableStackEffect,
ITERPOP: 0,
ITERPUSH: -1,
JMP: 0,
LE: -1,
LOAD: -1,
LOCAL: +1,
LT: -1,
LTLT: -1,
MAKEDICT: +1,
MAKEFUNC: -1,
MAKELIST: variableStackEffect,
MAKETUPLE: variableStackEffect,
MINUS: -1,
NEQ: -1,
NONE: +1,
NOP: 0,
NOT: 0,
PERCENT: -1,
PIPE: -1,
PLUS: -1,
POP: -1,
PREDECLARED: +1,
RETURN: -1,
SETDICT: -3,
SETDICTUNIQ: -3,
SETFIELD: -2,
SETGLOBAL: -1,
SETINDEX: -3,
SETLOCAL: -1,
SLASH: -1,
SLASHSLASH: -1,
SLICE: -3,
STAR: -1,
TRUE: +1,
UNIVERSAL: +1,
UNPACK: variableStackEffect,
}
func (op Opcode) String() string {
if op < OpcodeMax {
return opcodeNames[op]
}
return fmt.Sprintf("illegal op (%d)", op)
}
// A Program is a Starlark file in executable form.
//
// Programs are serialized by the gobProgram function,
// which must be updated whenever this declaration is changed.
type Program struct {
Loads []Ident // name (really, string) and position of each load stmt
Names []string // names of attributes and predeclared variables
Constants []interface{} // = string | int64 | float64 | *big.Int
Functions []*Funcode
Globals []Ident // for error messages and tracing
Toplevel *Funcode // module initialization function
}
// A Funcode is the code of a compiled Starlark function.
//
// Funcodes are serialized by the gobFunc function,
// which must be updated whenever this declaration is changed.
type Funcode struct {
Prog *Program
Pos syntax.Position // position of def or lambda token
Name string // name of this function
Code []byte // the byte code
pclinetab []uint16 // mapping from pc to linenum
Locals []Ident // for error messages and tracing
Freevars []Ident // for tracing
MaxStack int
NumParams int
HasVarargs, HasKwargs bool
}
// An Ident is the name and position of an identifier.
type Ident struct {
Name string
Pos syntax.Position
}
// A pcomp holds the compiler state for a Program.
type pcomp struct {
prog *Program // what we're building
names map[string]uint32
constants map[interface{}]uint32
functions map[*Funcode]uint32
}
// An fcomp holds the compiler state for a Funcode.
type fcomp struct {
fn *Funcode // what we're building
pcomp *pcomp
pos syntax.Position // current position of generated code
loops []loop
block *block
}
type loop struct {
break_, continue_ *block
}
type block struct {
insns []insn
// If the last insn is a RETURN, jmp and cjmp are nil.
// If the last insn is a CJMP or ITERJMP,
// cjmp and jmp are the "true" and "false" successors.
// Otherwise, jmp is the sole successor.
jmp, cjmp *block
initialstack int // for stack depth computation
// Used during encoding
index int // -1 => not encoded yet
addr uint32
}
type insn struct {
op Opcode
arg uint32
line int32
}
func (fn *Funcode) Position(pc uint32) syntax.Position {
// Conceptually the table contains rows of the form (pc uint32,
// line int32). Since the pc always increases, usually by a
// small amount, and the line number typically also does too
// although it may decrease, again typically by a small amount,
// we use delta encoding, starting from {pc: 0, line: 0}.
//
// Each entry is encoded in 16 bits.
// The top 8 bits are the unsigned delta pc; the next 7 bits are
// the signed line number delta; and the bottom bit indicates
// that more rows follow because one of the deltas was maxed out.
//
// TODO(adonovan): opt: improve the encoding; include the column.
pos := fn.Pos // copy the (annoyingly inaccessible) filename
pos.Line = 0
pos.Col = 0
// Position returns the record for the
// largest PC value not greater than 'pc'.
var prevpc uint32
complete := true
for _, x := range fn.pclinetab {
nextpc := prevpc + uint32(x>>8)
if complete && nextpc > pc {
return pos
}
prevpc = nextpc
pos.Line += int32(int8(x) >> 1) // sign extend Δline from 7 to 32 bits
complete = (x & 1) == 0
}
return pos
}
// idents convert syntactic identifiers to compiled form.
func idents(ids []*syntax.Ident) []Ident {
res := make([]Ident, len(ids))
for i, id := range ids {
res[i].Name = id.Name
res[i].Pos = id.NamePos
}
return res
}
// Expr compiles an expression to a program consisting of a single toplevel function.
func Expr(expr syntax.Expr, locals []*syntax.Ident) *Funcode {
stmts := []syntax.Stmt{&syntax.ReturnStmt{Result: expr}}
return File(stmts, locals, nil).Toplevel
}
// File compiles the statements of a file into a program.
func File(stmts []syntax.Stmt, locals, globals []*syntax.Ident) *Program {
pcomp := &pcomp{
prog: &Program{
Globals: idents(globals),
},
names: make(map[string]uint32),
constants: make(map[interface{}]uint32),
functions: make(map[*Funcode]uint32),
}
var pos syntax.Position
if len(stmts) > 0 {
pos = syntax.Start(stmts[0])
}
pcomp.prog.Toplevel = pcomp.function("<toplevel>", pos, stmts, locals, nil)
return pcomp.prog
}
func (pcomp *pcomp) function(name string, pos syntax.Position, stmts []syntax.Stmt, locals, freevars []*syntax.Ident) *Funcode {
fcomp := &fcomp{
pcomp: pcomp,
pos: pos,
fn: &Funcode{
Prog: pcomp.prog,
Pos: pos,
Name: name,
Locals: idents(locals),
Freevars: idents(freevars),
},
}
if debug {
fmt.Fprintf(os.Stderr, "start function(%s @ %s)\n", name, pos)
}
// Convert AST to a CFG of instructions.
entry := fcomp.newBlock()
fcomp.block = entry
fcomp.stmts(stmts)
if fcomp.block != nil {
fcomp.emit(NONE)
fcomp.emit(RETURN)
}
var oops bool // something bad happened
setinitialstack := func(b *block, depth int) {
if b.initialstack == -1 {
b.initialstack = depth
} else if b.initialstack != depth {
fmt.Fprintf(os.Stderr, "%d: setinitialstack: depth mismatch: %d vs %d\n",
b.index, b.initialstack, depth)
oops = true
}
}
// Linearize the CFG:
// compute order, address, and initial
// stack depth of each reachable block.
var pc uint32
var blocks []*block
var maxstack int
var visit func(b *block)
visit = func(b *block) {
if b.index >= 0 {
return // already visited
}
b.index = len(blocks)
b.addr = pc
blocks = append(blocks, b)
stack := b.initialstack
if debug {
fmt.Fprintf(os.Stderr, "%s block %d: (stack = %d)\n", name, b.index, stack)
}
var cjmpAddr *uint32
var isiterjmp int
for i, insn := range b.insns {
pc++
// Compute size of argument.
if insn.op >= OpcodeArgMin {
switch insn.op {
case ITERJMP:
isiterjmp = 1
fallthrough
case CJMP:
cjmpAddr = &b.insns[i].arg
pc += 4
default:
pc += uint32(argLen(insn.arg))
}
}
// Compute effect on stack.
se := insn.stackeffect()
if debug {
fmt.Fprintln(os.Stderr, "\t", insn.op, stack, stack+se)
}
stack += se
if stack < 0 {
fmt.Fprintf(os.Stderr, "After pc=%d: stack underflow\n", pc)
oops = true
}
if stack+isiterjmp > maxstack {
maxstack = stack + isiterjmp
}
}
if debug {
fmt.Fprintf(os.Stderr, "successors of block %d (start=%d):\n",
b.addr, b.index)
if b.jmp != nil {
fmt.Fprintf(os.Stderr, "jmp to %d\n", b.jmp.index)
}
if b.cjmp != nil {
fmt.Fprintf(os.Stderr, "cjmp to %d\n", b.cjmp.index)
}
}
// Place the jmp block next.
if b.jmp != nil {
// jump threading (empty cycles are impossible)
for b.jmp.insns == nil {
b.jmp = b.jmp.jmp
}
setinitialstack(b.jmp, stack+isiterjmp)
if b.jmp.index < 0 {
// Successor is not yet visited:
// place it next and fall through.
visit(b.jmp)
} else {
// Successor already visited;
// explicit backward jump required.
pc += 5
}
}
// Then the cjmp block.
if b.cjmp != nil {
// jump threading (empty cycles are impossible)
for b.cjmp.insns == nil {
b.cjmp = b.cjmp.jmp
}
setinitialstack(b.cjmp, stack)
visit(b.cjmp)
// Patch the CJMP/ITERJMP, if present.
if cjmpAddr != nil {
*cjmpAddr = b.cjmp.addr
}
}
}
setinitialstack(entry, 0)
visit(entry)
fn := fcomp.fn
fn.MaxStack = maxstack
// Emit bytecode (and position table).
if debug {
fmt.Fprintf(os.Stderr, "Function %s: (%d blocks, %d bytes)\n", name, len(blocks), pc)
}
fcomp.generate(blocks, pc)
if debug {
fmt.Fprintf(os.Stderr, "code=%d maxstack=%d\n", fn.Code, fn.MaxStack)
}
// Don't panic until we've completed printing of the function.
if oops {
panic("internal error")
}
if debug {
fmt.Fprintf(os.Stderr, "end function(%s @ %s)\n", name, pos)
}
return fn
}
func (insn *insn) stackeffect() int {
se := int(stackEffect[insn.op])
if se == variableStackEffect {
arg := int(insn.arg)
switch insn.op {
case CALL, CALL_KW, CALL_VAR, CALL_VAR_KW:
se = -int(2*(insn.arg&0xff) + insn.arg>>8)
if insn.op != CALL {
se--
}
if insn.op == CALL_VAR_KW {
se--
}
case ITERJMP:
// Stack effect differs by successor:
// +1 for jmp/false/ok
// 0 for cjmp/true/exhausted
// Handled specially in caller.
se = 0
case MAKELIST, MAKETUPLE:
se = 1 - arg
case UNPACK:
se = arg - 1
default:
panic(insn.op)
}
}
return se
}
// generate emits the linear instruction stream from the CFG,
// and builds the PC-to-line number table.
func (fcomp *fcomp) generate(blocks []*block, codelen uint32) {
code := make([]byte, 0, codelen)
var pclinetab []uint16
var prev struct {
pc uint32
line int32
}
for _, b := range blocks {
if debug {
fmt.Fprintf(os.Stderr, "%d:\n", b.index)
}
pc := b.addr
for _, insn := range b.insns {
if insn.line != 0 {
// Instruction has a source position. Delta-encode it.
// See Funcode.Position for the encoding.
for {
var incomplete uint16
deltapc := pc - prev.pc
if deltapc > 0xff {
deltapc = 0xff
incomplete = 1
}
prev.pc += deltapc
deltaline := insn.line - prev.line
if deltaline > 0x3f {
deltaline = 0x3f
incomplete = 1
} else if deltaline < -0x40 {
deltaline = -0x40
incomplete = 1
}
prev.line += deltaline
entry := uint16(deltapc<<8) | uint16(uint8(deltaline<<1)) | incomplete
pclinetab = append(pclinetab, entry)
if incomplete == 0 {
break
}
}
if debug {
fmt.Fprintf(os.Stderr, "\t\t\t\t\t; %s %d\n",
filepath.Base(fcomp.fn.Pos.Filename()), insn.line)
}
}
if debug {
PrintOp(fcomp.fn, pc, insn.op, insn.arg)
}
code = append(code, byte(insn.op))
pc++
if insn.op >= OpcodeArgMin {
if insn.op == CJMP || insn.op == ITERJMP {
code = addUint32(code, insn.arg, 4) // pad arg to 4 bytes
} else {
code = addUint32(code, insn.arg, 0)
}
pc = uint32(len(code))
}
}
if b.jmp != nil && b.jmp.index != b.index+1 {
addr := b.jmp.addr
if debug {
fmt.Fprintf(os.Stderr, "\t%d\tjmp\t\t%d\t; block %d\n",
pc, addr, b.jmp.index)
}
code = append(code, byte(JMP))
code = addUint32(code, addr, 4)
}
}
if len(code) != int(codelen) {
panic("internal error: wrong code length")
}
fcomp.fn.pclinetab = pclinetab
fcomp.fn.Code = code
}
// addUint32 encodes x as 7-bit little-endian varint.
// TODO(adonovan): opt: steal top two bits of opcode
// to encode the number of complete bytes that follow.
func addUint32(code []byte, x uint32, min int) []byte {
end := len(code) + min
for x >= 0x80 {
code = append(code, byte(x)|0x80)
x >>= 7
}
code = append(code, byte(x))
// Pad the operand with NOPs to exactly min bytes.
for len(code) < end {
code = append(code, byte(NOP))
}
return code
}
func argLen(x uint32) int {
n := 0
for x >= 0x80 {
n++
x >>= 7
}
return n + 1
}
// PrintOp prints an instruction.
// It is provided for debugging.
func PrintOp(fn *Funcode, pc uint32, op Opcode, arg uint32) {
if op < OpcodeArgMin {
fmt.Fprintf(os.Stderr, "\t%d\t%s\n", pc, op)
return
}
var comment string
switch op {
case CONSTANT:
switch x := fn.Prog.Constants[arg].(type) {
case string:
comment = strconv.Quote(x)
default:
comment = fmt.Sprint(x)
}
case MAKEFUNC:
comment = fn.Prog.Functions[arg].Name
case SETLOCAL, LOCAL:
comment = fn.Locals[arg].Name
case SETGLOBAL, GLOBAL:
comment = fn.Prog.Globals[arg].Name
case ATTR, SETFIELD, PREDECLARED, UNIVERSAL:
comment = fn.Prog.Names[arg]
case FREE:
comment = fn.Freevars[arg].Name
case CALL, CALL_VAR, CALL_KW, CALL_VAR_KW:
comment = fmt.Sprintf("%d pos, %d named", arg>>8, arg&0xff)
default:
// JMP, CJMP, ITERJMP, MAKETUPLE, MAKELIST, LOAD, UNPACK:
// arg is just a number
}
var buf bytes.Buffer
fmt.Fprintf(&buf, "\t%d\t%-10s\t%d", pc, op, arg)
if comment != "" {
fmt.Fprint(&buf, "\t; ", comment)
}
fmt.Fprintln(&buf)
os.Stderr.Write(buf.Bytes())
}
// newBlock returns a new block.
func (fcomp) newBlock() *block {
return &block{index: -1, initialstack: -1}
}
// emit emits an instruction to the current block.
func (fcomp *fcomp) emit(op Opcode) {
if op >= OpcodeArgMin {
panic("missing arg: " + op.String())
}
insn := insn{op: op, line: fcomp.pos.Line}
fcomp.block.insns = append(fcomp.block.insns, insn)
fcomp.pos.Line = 0
}
// emit1 emits an instruction with an immediate operand.
func (fcomp *fcomp) emit1(op Opcode, arg uint32) {
if op < OpcodeArgMin {
panic("unwanted arg: " + op.String())
}
insn := insn{op: op, arg: arg, line: fcomp.pos.Line}
fcomp.block.insns = append(fcomp.block.insns, insn)
fcomp.pos.Line = 0
}
// jump emits a jump to the specified block.
// On return, the current block is unset.
func (fcomp *fcomp) jump(b *block) {
if b == fcomp.block {
panic("self-jump") // unreachable: Starlark has no arbitrary looping constructs
}
fcomp.block.jmp = b
fcomp.block = nil
}
// condjump emits a conditional jump (CJMP or ITERJMP)
// to the specified true/false blocks.
// (For ITERJMP, the cases are jmp/f/ok and cjmp/t/exhausted.)
// On return, the current block is unset.
func (fcomp *fcomp) condjump(op Opcode, t, f *block) {
if !(op == CJMP || op == ITERJMP) {
panic("not a conditional jump: " + op.String())
}
fcomp.emit1(op, 0) // fill in address later
fcomp.block.cjmp = t
fcomp.jump(f)
}
// nameIndex returns the index of the specified name
// within the name pool, adding it if necessary.
func (pcomp *pcomp) nameIndex(name string) uint32 {
index, ok := pcomp.names[name]
if !ok {
index = uint32(len(pcomp.prog.Names))
pcomp.names[name] = index
pcomp.prog.Names = append(pcomp.prog.Names, name)
}
return index
}
// constantIndex returns the index of the specified constant
// within the constant pool, adding it if necessary.
func (pcomp *pcomp) constantIndex(v interface{}) uint32 {
index, ok := pcomp.constants[v]
if !ok {
index = uint32(len(pcomp.prog.Constants))
pcomp.constants[v] = index
pcomp.prog.Constants = append(pcomp.prog.Constants, v)
}
return index
}
// functionIndex returns the index of the specified function
// AST the nestedfun pool, adding it if necessary.
func (pcomp *pcomp) functionIndex(fn *Funcode) uint32 {
index, ok := pcomp.functions[fn]
if !ok {
index = uint32(len(pcomp.prog.Functions))
pcomp.functions[fn] = index
pcomp.prog.Functions = append(pcomp.prog.Functions, fn)
}
return index
}
// string emits code to push the specified string.
func (fcomp *fcomp) string(s string) {
fcomp.emit1(CONSTANT, fcomp.pcomp.constantIndex(s))
}
// setPos sets the current source position.
// It should be called prior to any operation that can fail dynamically.
// All positions are assumed to belong to the same file.
func (fcomp *fcomp) setPos(pos syntax.Position) {
fcomp.pos = pos
}
// set emits code to store the top-of-stack value
// to the specified local or global variable.
func (fcomp *fcomp) set(id *syntax.Ident) {
switch resolve.Scope(id.Scope) {
case resolve.Local:
fcomp.emit1(SETLOCAL, uint32(id.Index))
case resolve.Global:
fcomp.emit1(SETGLOBAL, uint32(id.Index))
default:
log.Fatalf("%s: set(%s): neither global nor local (%d)", id.NamePos, id.Name, id.Scope)
}
}
// lookup emits code to push the value of the specified variable.
func (fcomp *fcomp) lookup(id *syntax.Ident) {
switch resolve.Scope(id.Scope) {
case resolve.Local:
fcomp.setPos(id.NamePos)
fcomp.emit1(LOCAL, uint32(id.Index))
case resolve.Free:
fcomp.emit1(FREE, uint32(id.Index))
case resolve.Global:
fcomp.setPos(id.NamePos)
fcomp.emit1(GLOBAL, uint32(id.Index))
case resolve.Predeclared:
fcomp.setPos(id.NamePos)
fcomp.emit1(PREDECLARED, fcomp.pcomp.nameIndex(id.Name))
case resolve.Universal:
fcomp.emit1(UNIVERSAL, fcomp.pcomp.nameIndex(id.Name))
default:
log.Fatalf("%s: compiler.lookup(%s): scope = %d", id.NamePos, id.Name, id.Scope)
}
}
func (fcomp *fcomp) stmts(stmts []syntax.Stmt) {
for _, stmt := range stmts {
fcomp.stmt(stmt)
}
}
func (fcomp *fcomp) stmt(stmt syntax.Stmt) {
switch stmt := stmt.(type) {
case *syntax.ExprStmt:
if _, ok := stmt.X.(*syntax.Literal); ok {
// Opt: don't compile doc comments only to pop them.
return
}
fcomp.expr(stmt.X)
fcomp.emit(POP)
case *syntax.BranchStmt:
// Resolver invariant: break/continue appear only within loops.
switch stmt.Token {
case syntax.PASS:
// no-op
case syntax.BREAK:
b := fcomp.loops[len(fcomp.loops)-1].break_
fcomp.jump(b)
fcomp.block = fcomp.newBlock() // dead code
case syntax.CONTINUE:
b := fcomp.loops[len(fcomp.loops)-1].continue_
fcomp.jump(b)
fcomp.block = fcomp.newBlock() // dead code
}
case *syntax.IfStmt:
// Keep consistent with CondExpr.
t := fcomp.newBlock()
f := fcomp.newBlock()
done := fcomp.newBlock()
fcomp.ifelse(stmt.Cond, t, f)
fcomp.block = t
fcomp.stmts(stmt.True)
fcomp.jump(done)
fcomp.block = f
fcomp.stmts(stmt.False)
fcomp.jump(done)
fcomp.block = done
case *syntax.AssignStmt:
switch stmt.Op {
case syntax.EQ:
// simple assignment: x = y
fcomp.expr(stmt.RHS)
fcomp.assign(stmt.OpPos, stmt.LHS)
case syntax.PLUS_EQ,
syntax.MINUS_EQ,
syntax.STAR_EQ,
syntax.SLASH_EQ,
syntax.SLASHSLASH_EQ,
syntax.PERCENT_EQ,
syntax.AMP_EQ,
syntax.PIPE_EQ,
syntax.CIRCUMFLEX_EQ,
syntax.LTLT_EQ,
syntax.GTGT_EQ:
// augmented assignment: x += y
var set func()
// Evaluate "address" of x exactly once to avoid duplicate side-effects.
switch lhs := stmt.LHS.(type) {
case *syntax.Ident:
// x = ...
fcomp.lookup(lhs)
set = func() {
fcomp.set(lhs)
}
case *syntax.IndexExpr:
// x[y] = ...
fcomp.expr(lhs.X)
fcomp.expr(lhs.Y)
fcomp.emit(DUP2)
fcomp.setPos(lhs.Lbrack)
fcomp.emit(INDEX)
set = func() {
fcomp.setPos(lhs.Lbrack)
fcomp.emit(SETINDEX)
}
case *syntax.DotExpr:
// x.f = ...
fcomp.expr(lhs.X)
fcomp.emit(DUP)
name := fcomp.pcomp.nameIndex(lhs.Name.Name)
fcomp.setPos(lhs.Dot)
fcomp.emit1(ATTR, name)
set = func() {
fcomp.setPos(lhs.Dot)
fcomp.emit1(SETFIELD, name)
}
default:
panic(lhs)
}
fcomp.expr(stmt.RHS)
if stmt.Op == syntax.PLUS_EQ {
// Allow the runtime to optimize list += iterable.
fcomp.setPos(stmt.OpPos)
fcomp.emit(INPLACE_ADD)
} else {
fcomp.binop(stmt.OpPos, stmt.Op-syntax.PLUS_EQ+syntax.PLUS)
}
set()
}
case *syntax.DefStmt:
fcomp.function(stmt.Def, stmt.Name.Name, &stmt.Function)
fcomp.set(stmt.Name)
case *syntax.ForStmt:
// Keep consistent with ForClause.
head := fcomp.newBlock()
body := fcomp.newBlock()
tail := fcomp.newBlock()
fcomp.expr(stmt.X)
fcomp.setPos(stmt.For)
fcomp.emit(ITERPUSH)
fcomp.jump(head)
fcomp.block = head
fcomp.condjump(ITERJMP, tail, body)
fcomp.block = body
fcomp.assign(stmt.For, stmt.Vars)
fcomp.loops = append(fcomp.loops, loop{break_: tail, continue_: head})
fcomp.stmts(stmt.Body)
fcomp.loops = fcomp.loops[:len(fcomp.loops)-1]
fcomp.jump(head)
fcomp.block = tail
fcomp.emit(ITERPOP)
case *syntax.ReturnStmt:
if stmt.Result != nil {
fcomp.expr(stmt.Result)
} else {
fcomp.emit(NONE)
}
fcomp.emit(RETURN)
fcomp.block = fcomp.newBlock() // dead code
case *syntax.LoadStmt:
for i := range stmt.From {
fcomp.string(stmt.From[i].Name)
}
module := stmt.Module.Value.(string)
fcomp.pcomp.prog.Loads = append(fcomp.pcomp.prog.Loads, Ident{
Name: module,
Pos: stmt.Module.TokenPos,
})
fcomp.string(module)
fcomp.setPos(stmt.Load)
fcomp.emit1(LOAD, uint32(len(stmt.From)))
for i := range stmt.To {
fcomp.emit1(SETGLOBAL, uint32(stmt.To[len(stmt.To)-1-i].Index))
}
default:
start, _ := stmt.Span()
log.Fatalf("%s: exec: unexpected statement %T", start, stmt)
}
}
// assign implements lhs = rhs for arbitrary expressions lhs.
// RHS is on top of stack, consumed.
func (fcomp *fcomp) assign(pos syntax.Position, lhs syntax.Expr) {
switch lhs := lhs.(type) {
case *syntax.ParenExpr:
// (lhs) = rhs
fcomp.assign(pos, lhs.X)
case *syntax.Ident:
// x = rhs
fcomp.set(lhs)
case *syntax.TupleExpr:
// x, y = rhs
fcomp.assignSequence(pos, lhs.List)
case *syntax.ListExpr:
// [x, y] = rhs
fcomp.assignSequence(pos, lhs.List)
case *syntax.IndexExpr:
// x[y] = rhs
fcomp.expr(lhs.X)
fcomp.emit(EXCH)
fcomp.expr(lhs.Y)
fcomp.emit(EXCH)
fcomp.setPos(lhs.Lbrack)
fcomp.emit(SETINDEX)
case *syntax.DotExpr:
// x.f = rhs
fcomp.expr(lhs.X)
fcomp.emit(EXCH)
fcomp.setPos(lhs.Dot)
fcomp.emit1(SETFIELD, fcomp.pcomp.nameIndex(lhs.Name.Name))
default:
panic(lhs)
}
}
func (fcomp *fcomp) assignSequence(pos syntax.Position, lhs []syntax.Expr) {
fcomp.setPos(pos)
fcomp.emit1(UNPACK, uint32(len(lhs)))
for i := range lhs {
fcomp.assign(pos, lhs[i])
}
}
func (fcomp *fcomp) expr(e syntax.Expr) {
switch e := e.(type) {
case *syntax.ParenExpr:
fcomp.expr(e.X)
case *syntax.Ident:
fcomp.lookup(e)
case *syntax.Literal:
// e.Value is int64, float64, *bigInt, or string.
fcomp.emit1(CONSTANT, fcomp.pcomp.constantIndex(e.Value))
case *syntax.ListExpr:
for _, x := range e.List {
fcomp.expr(x)
}
fcomp.emit1(MAKELIST, uint32(len(e.List)))
case *syntax.CondExpr:
// Keep consistent with IfStmt.
t := fcomp.newBlock()
f := fcomp.newBlock()
done := fcomp.newBlock()
fcomp.ifelse(e.Cond, t, f)
fcomp.block = t
fcomp.expr(e.True)
fcomp.jump(done)
fcomp.block = f
fcomp.expr(e.False)
fcomp.jump(done)
fcomp.block = done
case *syntax.IndexExpr:
fcomp.expr(e.X)
fcomp.expr(e.Y)
fcomp.setPos(e.Lbrack)
fcomp.emit(INDEX)
case *syntax.SliceExpr:
fcomp.setPos(e.Lbrack)
fcomp.expr(e.X)
if e.Lo != nil {
fcomp.expr(e.Lo)
} else {
fcomp.emit(NONE)
}
if e.Hi != nil {
fcomp.expr(e.Hi)
} else {
fcomp.emit(NONE)
}
if e.Step != nil {
fcomp.expr(e.Step)
} else {
fcomp.emit(NONE)
}
fcomp.emit(SLICE)
case *syntax.Comprehension:
if e.Curly {
fcomp.emit(MAKEDICT)
} else {
fcomp.emit1(MAKELIST, 0)
}
fcomp.comprehension(e, 0)
case *syntax.TupleExpr:
fcomp.tuple(e.List)
case *syntax.DictExpr:
fcomp.emit(MAKEDICT)
for _, entry := range e.List {
entry := entry.(*syntax.DictEntry)
fcomp.emit(DUP)
fcomp.expr(entry.Key)
fcomp.expr(entry.Value)
fcomp.setPos(entry.Colon)
fcomp.emit(SETDICTUNIQ)
}
case *syntax.UnaryExpr:
fcomp.expr(e.X)
fcomp.setPos(e.OpPos)
switch e.Op {
case syntax.MINUS:
fcomp.emit(UMINUS)
case syntax.PLUS:
fcomp.emit(UPLUS)
case syntax.NOT:
fcomp.emit(NOT)
case syntax.TILDE:
fcomp.emit(TILDE)
default:
log.Fatalf("%s: unexpected unary op: %s", e.OpPos, e.Op)
}
case *syntax.BinaryExpr:
switch e.Op {
// short-circuit operators
// TODO(adonovan): use ifelse to simplify conditions.
case syntax.OR:
// x or y => if x then x else y
done := fcomp.newBlock()
y := fcomp.newBlock()
fcomp.expr(e.X)
fcomp.emit(DUP)
fcomp.condjump(CJMP, done, y)
fcomp.block = y
fcomp.emit(POP) // discard X
fcomp.expr(e.Y)
fcomp.jump(done)
fcomp.block = done
case syntax.AND:
// x and y => if x then y else x
done := fcomp.newBlock()
y := fcomp.newBlock()
fcomp.expr(e.X)
fcomp.emit(DUP)
fcomp.condjump(CJMP, y, done)
fcomp.block = y
fcomp.emit(POP) // discard X
fcomp.expr(e.Y)
fcomp.jump(done)
fcomp.block = done
case syntax.PLUS:
fcomp.plus(e)
default:
// all other strict binary operator (includes comparisons)
fcomp.expr(e.X)
fcomp.expr(e.Y)
fcomp.binop(e.OpPos, e.Op)
}
case *syntax.DotExpr:
fcomp.expr(e.X)
fcomp.setPos(e.Dot)
fcomp.emit1(ATTR, fcomp.pcomp.nameIndex(e.Name.Name))
case *syntax.CallExpr:
fcomp.call(e)
case *syntax.LambdaExpr:
fcomp.function(e.Lambda, "lambda", &e.Function)
default:
start, _ := e.Span()
log.Fatalf("%s: unexpected expr %T", start, e)
}
}
type summand struct {
x syntax.Expr
plusPos syntax.Position
}
// plus emits optimized code for ((a+b)+...)+z that avoids naive
// quadratic behavior for strings, tuples, and lists,
// and folds together adjacent literals of the same type.
func (fcomp *fcomp) plus(e *syntax.BinaryExpr) {
// Gather all the right operands of the left tree of plusses.
// A tree (((a+b)+c)+d) becomes args=[a +b +c +d].
args := make([]summand, 0, 2) // common case: 2 operands
for plus := e; ; {
args = append(args, summand{unparen(plus.Y), plus.OpPos})
left := unparen(plus.X)
x, ok := left.(*syntax.BinaryExpr)
if !ok || x.Op != syntax.PLUS {
args = append(args, summand{x: left})
break
}
plus = x
}
// Reverse args to syntactic order.
for i, n := 0, len(args)/2; i < n; i++ {
j := len(args) - 1 - i
args[i], args[j] = args[j], args[i]
}
// Fold sums of adjacent literals of the same type: ""+"", []+[], ()+().
out := args[:0] // compact in situ
for i := 0; i < len(args); {
j := i + 1
if code := addable(args[i].x); code != 0 {
for j < len(args) && addable(args[j].x) == code {
j++
}
if j > i+1 {
args[i].x = add(code, args[i:j])
}
}
out = append(out, args[i])
i = j
}
args = out
// Emit code for an n-ary sum (n > 0).
fcomp.expr(args[0].x)
for _, summand := range args[1:] {
fcomp.expr(summand.x)
fcomp.setPos(summand.plusPos)
fcomp.emit(PLUS)
}
// If len(args) > 2, use of an accumulator instead of a chain of
// PLUS operations may be more efficient.
// However, no gain was measured on a workload analogous to Bazel loading;
// TODO(adonovan): opt: re-evaluate on a Bazel analysis-like workload.
//
// We cannot use a single n-ary SUM operation
// a b c SUM<3>
// because we need to report a distinct error for each
// individual '+' operation, so three additional operations are
// needed:
//
// ACCSTART => create buffer and append to it
// ACCUM => append to buffer
// ACCEND => get contents of buffer
//
// For string, list, and tuple values, the interpreter can
// optimize these operations by using a mutable buffer.
// For all other types, ACCSTART and ACCEND would behave like
// the identity function and ACCUM behaves like PLUS.
// ACCUM must correctly support user-defined operations
// such as list+foo.
//
// fcomp.emit(ACCSTART)
// for _, summand := range args[1:] {
// fcomp.expr(summand.x)
// fcomp.setPos(summand.plusPos)
// fcomp.emit(ACCUM)
// }
// fcomp.emit(ACCEND)
}
// addable reports whether e is a statically addable
// expression: a [s]tring, [l]ist, or [t]uple.
func addable(e syntax.Expr) rune {
switch e := e.(type) {
case *syntax.Literal:
// TODO(adonovan): opt: support INT/FLOAT/BIGINT constant folding.
switch e.Token {
case syntax.STRING:
return 's'
}
case *syntax.ListExpr:
return 'l'
case *syntax.TupleExpr:
return 't'
}
return 0
}
// add returns an expression denoting the sum of args,
// which are all addable values of the type indicated by code.
// The resulting syntax is degenerate, lacking position, etc.
func add(code rune, args []summand) syntax.Expr {
switch code {
case 's':
var buf bytes.Buffer
for _, arg := range args {
buf.WriteString(arg.x.(*syntax.Literal).Value.(string))
}
return &syntax.Literal{Token: syntax.STRING, Value: buf.String()}
case 'l':
var elems []syntax.Expr
for _, arg := range args {
elems = append(elems, arg.x.(*syntax.ListExpr).List...)
}
return &syntax.ListExpr{List: elems}
case 't':
var elems []syntax.Expr
for _, arg := range args {
elems = append(elems, arg.x.(*syntax.TupleExpr).List...)
}
return &syntax.TupleExpr{List: elems}
}
panic(code)
}
func unparen(e syntax.Expr) syntax.Expr {
if p, ok := e.(*syntax.ParenExpr); ok {
return unparen(p.X)
}
return e
}
func (fcomp *fcomp) binop(pos syntax.Position, op syntax.Token) {
// TODO(adonovan): simplify by assuming syntax and compiler constants align.
fcomp.setPos(pos)
switch op {
// arithmetic
case syntax.PLUS:
fcomp.emit(PLUS)
case syntax.MINUS:
fcomp.emit(MINUS)
case syntax.STAR:
fcomp.emit(STAR)
case syntax.SLASH:
fcomp.emit(SLASH)
case syntax.SLASHSLASH:
fcomp.emit(SLASHSLASH)
case syntax.PERCENT:
fcomp.emit(PERCENT)
case syntax.AMP:
fcomp.emit(AMP)
case syntax.PIPE:
fcomp.emit(PIPE)
case syntax.CIRCUMFLEX:
fcomp.emit(CIRCUMFLEX)
case syntax.LTLT:
fcomp.emit(LTLT)
case syntax.GTGT:
fcomp.emit(GTGT)
case syntax.IN:
fcomp.emit(IN)
case syntax.NOT_IN:
fcomp.emit(IN)
fcomp.emit(NOT)
// comparisons
case syntax.EQL,
syntax.NEQ,
syntax.GT,
syntax.LT,
syntax.LE,
syntax.GE:
fcomp.emit(Opcode(op-syntax.EQL) + EQL)
default:
log.Fatalf("%s: unexpected binary op: %s", pos, op)
}
}
func (fcomp *fcomp) call(call *syntax.CallExpr) {
// TODO(adonovan): opt: Use optimized path for calling methods
// of built-ins: x.f(...) to avoid materializing a closure.
// if dot, ok := call.Fcomp.(*syntax.DotExpr); ok {
// fcomp.expr(dot.X)
// fcomp.args(call)
// fcomp.emit1(CALL_ATTR, fcomp.name(dot.Name.Name))
// return
// }
// usual case
fcomp.expr(call.Fn)
op, arg := fcomp.args(call)
fcomp.setPos(call.Lparen)
fcomp.emit1(op, arg)
}
// args emits code to push a tuple of positional arguments
// and a tuple of named arguments containing alternating keys and values.
// Either or both tuples may be empty (TODO(adonovan): optimize).
func (fcomp *fcomp) args(call *syntax.CallExpr) (op Opcode, arg uint32) {
var callmode int
// Compute the number of each kind of parameter.
var p, n int // number of positional, named arguments
var varargs, kwargs syntax.Expr
for _, arg := range call.Args {
if binary, ok := arg.(*syntax.BinaryExpr); ok && binary.Op == syntax.EQ {
// named argument (name, value)
fcomp.string(binary.X.(*syntax.Ident).Name)
fcomp.expr(binary.Y)
n++
continue
}
if unary, ok := arg.(*syntax.UnaryExpr); ok {
if unary.Op == syntax.STAR {
callmode |= 1
varargs = unary.X
continue
} else if unary.Op == syntax.STARSTAR {
callmode |= 2
kwargs = unary.X
continue
}
}
// positional argument
fcomp.expr(arg)
p++
}
// Python2, Python3, and Starlark-in-Java all permit named arguments
// to appear both before and after a *args argument:
// f(1, 2, x=3, *[4], y=5, **dict(z=6))
//
// However all three implement different argument evaluation orders:
// Python2: 1 2 3 5 4 6 (*args and **kwargs evaluated last)
// Python3: 1 2 4 3 5 6 (positional args evaluated before named args)
// Starlark-in-Java: 1 2 3 4 5 6 (lexical order)
//
// The Starlark-in-Java semantics are clean but hostile to a
// compiler-based implementation because they require that the
// compiler emit code for positional, named, *args, more named,
// and *kwargs arguments and provide the callee with a map of
// the terrain.
//
// For now we implement the Python2 semantics, but
// the spec needs to clarify the correct approach.
// Perhaps it would be best if we statically rejected
// named arguments after *args (e.g. y=5) so that the
// Python2 implementation strategy matches lexical order.
// Discussion in github.com/bazelbuild/starlark#13.
// *args
if varargs != nil {
fcomp.expr(varargs)
}
// **kwargs
if kwargs != nil {
fcomp.expr(kwargs)
}
// TODO(adonovan): avoid this with a more flexible encoding.
if p >= 256 || n >= 256 {
log.Fatalf("%s: compiler error: too many arguments in call", call.Lparen)
}
return CALL + Opcode(callmode), uint32(p<<8 | n)
}
func (fcomp *fcomp) tuple(elems []syntax.Expr) {
for _, elem := range elems {
fcomp.expr(elem)
}
fcomp.emit1(MAKETUPLE, uint32(len(elems)))
}
func (fcomp *fcomp) comprehension(comp *syntax.Comprehension, clauseIndex int) {
if clauseIndex == len(comp.Clauses) {
fcomp.emit(DUP) // accumulator
if comp.Curly {
// dict: {k:v for ...}
// Parser ensures that body is of form k:v.
// Python-style set comprehensions {body for vars in x}
// are not supported.
entry := comp.Body.(*syntax.DictEntry)
fcomp.expr(entry.Key)
fcomp.expr(entry.Value)
fcomp.setPos(entry.Colon)
fcomp.emit(SETDICT)
} else {
// list: [body for vars in x]
fcomp.expr(comp.Body)
fcomp.emit(APPEND)
}
return
}
clause := comp.Clauses[clauseIndex]
switch clause := clause.(type) {
case *syntax.IfClause:
t := fcomp.newBlock()
done := fcomp.newBlock()
fcomp.ifelse(clause.Cond, t, done)
fcomp.block = t
fcomp.comprehension(comp, clauseIndex+1)
fcomp.jump(done)
fcomp.block = done
return
case *syntax.ForClause:
// Keep consistent with ForStmt.
head := fcomp.newBlock()
body := fcomp.newBlock()
tail := fcomp.newBlock()
fcomp.expr(clause.X)
fcomp.setPos(clause.For)
fcomp.emit(ITERPUSH)
fcomp.jump(head)
fcomp.block = head
fcomp.condjump(ITERJMP, tail, body)
fcomp.block = body
fcomp.assign(clause.For, clause.Vars)
fcomp.comprehension(comp, clauseIndex+1)
fcomp.jump(head)
fcomp.block = tail
fcomp.emit(ITERPOP)
return
}
start, _ := clause.Span()
log.Fatalf("%s: unexpected comprehension clause %T", start, clause)
}
func (fcomp *fcomp) function(pos syntax.Position, name string, f *syntax.Function) {
// Evalution of the elements of both MAKETUPLEs may fail,
// so record the position.
fcomp.setPos(pos)
// Generate tuple of parameter defaults.
n := 0
for _, param := range f.Params {
if binary, ok := param.(*syntax.BinaryExpr); ok {
fcomp.expr(binary.Y)
n++
}
}
fcomp.emit1(MAKETUPLE, uint32(n))
// Capture the values of the function's
// free variables from the lexical environment.
for _, freevar := range f.FreeVars {
fcomp.lookup(freevar)
}
fcomp.emit1(MAKETUPLE, uint32(len(f.FreeVars)))
funcode := fcomp.pcomp.function(name, pos, f.Body, f.Locals, f.FreeVars)
if debug {
// TODO(adonovan): do compilations sequentially not as a tree,
// to make the log easier to read.
// Simplify by identifying Toplevel and functionIndex 0.
fmt.Fprintf(os.Stderr, "resuming %s @ %s\n", fcomp.fn.Name, fcomp.pos)
}
funcode.NumParams = len(f.Params)
funcode.HasVarargs = f.HasVarargs
funcode.HasKwargs = f.HasKwargs
fcomp.emit1(MAKEFUNC, fcomp.pcomp.functionIndex(funcode))
}
// ifelse emits a Boolean control flow decision.
// On return, the current block is unset.
func (fcomp *fcomp) ifelse(cond syntax.Expr, t, f *block) {
switch cond := cond.(type) {
case *syntax.UnaryExpr:
if cond.Op == syntax.NOT {
// if not x then goto t else goto f
// =>
// if x then goto f else goto t
fcomp.ifelse(cond.X, f, t)
return
}
case *syntax.BinaryExpr:
switch cond.Op {
case syntax.AND:
// if x and y then goto t else goto f
// =>
// if x then ifelse(y, t, f) else goto f
fcomp.expr(cond.X)
y := fcomp.newBlock()
fcomp.condjump(CJMP, y, f)
fcomp.block = y
fcomp.ifelse(cond.Y, t, f)
return
case syntax.OR:
// if x or y then goto t else goto f
// =>
// if x then goto t else ifelse(y, t, f)
fcomp.expr(cond.X)
y := fcomp.newBlock()
fcomp.condjump(CJMP, t, y)
fcomp.block = y
fcomp.ifelse(cond.Y, t, f)
return
case syntax.NOT_IN:
// if x not in y then goto t else goto f
// =>
// if x in y then goto f else goto t
copy := *cond
copy.Op = syntax.IN
fcomp.expr(&copy)
fcomp.condjump(CJMP, f, t)
return
}
}
// general case
fcomp.expr(cond)
fcomp.condjump(CJMP, t, f)
}