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// Copyright 2019 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// +build ignore
// mkpreempt generates the asyncPreempt functions for each
// architecture.
package main
import (
"flag"
"fmt"
"io"
"log"
"os"
"strings"
)
// Copied from cmd/compile/internal/ssa/gen/*Ops.go
var regNames386 = []string{
"AX",
"CX",
"DX",
"BX",
"SP",
"BP",
"SI",
"DI",
"X0",
"X1",
"X2",
"X3",
"X4",
"X5",
"X6",
"X7",
}
var regNamesAMD64 = []string{
"AX",
"CX",
"DX",
"BX",
"SP",
"BP",
"SI",
"DI",
"R8",
"R9",
"R10",
"R11",
"R12",
"R13",
"R14",
"R15",
"X0",
"X1",
"X2",
"X3",
"X4",
"X5",
"X6",
"X7",
"X8",
"X9",
"X10",
"X11",
"X12",
"X13",
"X14",
"X15",
}
var out io.Writer
var arches = map[string]func(){
"386": gen386,
"amd64": genAMD64,
"arm": genARM,
"arm64": genARM64,
"mips64x": func() { genMIPS(true) },
"mipsx": func() { genMIPS(false) },
"ppc64x": genPPC64,
"riscv": genRISCV,
"riscv64": genRISCV64,
"s390x": genS390X,
"wasm": genWasm,
}
var beLe = map[string]bool{"mips64x": true, "mipsx": true, "ppc64x": true}
func main() {
flag.Parse()
if flag.NArg() > 0 {
out = os.Stdout
for _, arch := range flag.Args() {
gen, ok := arches[arch]
if !ok {
log.Fatalf("unknown arch %s", arch)
}
header(arch)
gen()
}
return
}
for arch, gen := range arches {
f, err := os.Create(fmt.Sprintf("preempt_%s.s", arch))
if err != nil {
log.Fatal(err)
}
out = f
header(arch)
gen()
if err := f.Close(); err != nil {
log.Fatal(err)
}
}
}
func header(arch string) {
fmt.Fprintf(out, "// Code generated by mkpreempt.go; DO NOT EDIT.\n\n")
if beLe[arch] {
base := arch[:len(arch)-1]
fmt.Fprintf(out, "// +build %s %sle\n\n", base, base)
}
fmt.Fprintf(out, "#include \"go_asm.h\"\n")
fmt.Fprintf(out, "#include \"textflag.h\"\n\n")
fmt.Fprintf(out, "// Note: asyncPreempt doesn't use the internal ABI, but we must be able to inject calls to it from the signal handler, so Go code has to see the PC of this function literally.\n")
fmt.Fprintf(out, "TEXT ·asyncPreempt<ABIInternal>(SB),NOSPLIT|NOFRAME,$0-0\n")
}
func p(f string, args ...interface{}) {
fmted := fmt.Sprintf(f, args...)
fmt.Fprintf(out, "\t%s\n", strings.ReplaceAll(fmted, "\n", "\n\t"))
}
func label(l string) {
fmt.Fprintf(out, "%s\n", l)
}
type layout struct {
stack int
regs []regPos
sp string // stack pointer register
}
type regPos struct {
pos int
op string
reg string
// If this register requires special save and restore, these
// give those operations with a %d placeholder for the stack
// offset.
save, restore string
}
func (l *layout) add(op, reg string, size int) {
l.regs = append(l.regs, regPos{op: op, reg: reg, pos: l.stack})
l.stack += size
}
func (l *layout) addSpecial(save, restore string, size int) {
l.regs = append(l.regs, regPos{save: save, restore: restore, pos: l.stack})
l.stack += size
}
func (l *layout) save() {
for _, reg := range l.regs {
if reg.save != "" {
p(reg.save, reg.pos)
} else {
p("%s %s, %d(%s)", reg.op, reg.reg, reg.pos, l.sp)
}
}
}
func (l *layout) restore() {
for i := len(l.regs) - 1; i >= 0; i-- {
reg := l.regs[i]
if reg.restore != "" {
p(reg.restore, reg.pos)
} else {
p("%s %d(%s), %s", reg.op, reg.pos, l.sp, reg.reg)
}
}
}
func gen386() {
p("PUSHFL")
// Save general purpose registers.
var l = layout{sp: "SP"}
for _, reg := range regNames386 {
if reg == "SP" || strings.HasPrefix(reg, "X") {
continue
}
l.add("MOVL", reg, 4)
}
// Save SSE state only if supported.
lSSE := layout{stack: l.stack, sp: "SP"}
for i := 0; i < 8; i++ {
lSSE.add("MOVUPS", fmt.Sprintf("X%d", i), 16)
}
p("ADJSP $%d", lSSE.stack)
p("NOP SP")
l.save()
p("CMPB internal∕cpu·X86+const_offsetX86HasSSE2(SB), $1\nJNE nosse")
lSSE.save()
label("nosse:")
p("CALL ·asyncPreempt2(SB)")
p("CMPB internal∕cpu·X86+const_offsetX86HasSSE2(SB), $1\nJNE nosse2")
lSSE.restore()
label("nosse2:")
l.restore()
p("ADJSP $%d", -lSSE.stack)
p("POPFL")
p("RET")
}
func genAMD64() {
// Assign stack offsets.
var l = layout{sp: "SP"}
for _, reg := range regNamesAMD64 {
if reg == "SP" || reg == "BP" {
continue
}
if strings.HasPrefix(reg, "X") {
l.add("MOVUPS", reg, 16)
} else {
l.add("MOVQ", reg, 8)
}
}
// TODO: MXCSR register?
p("PUSHQ BP")
p("MOVQ SP, BP")
p("// Save flags before clobbering them")
p("PUSHFQ")
p("// obj doesn't understand ADD/SUB on SP, but does understand ADJSP")
p("ADJSP $%d", l.stack)
p("// But vet doesn't know ADJSP, so suppress vet stack checking")
p("NOP SP")
// Apparently, the signal handling code path in darwin kernel leaves
// the upper bits of Y registers in a dirty state, which causes
// many SSE operations (128-bit and narrower) become much slower.
// Clear the upper bits to get to a clean state. See issue #37174.
// It is safe here as Go code don't use the upper bits of Y registers.
p("#ifdef GOOS_darwin")
p("CMPB internal∕cpu·X86+const_offsetX86HasAVX(SB), $0")
p("JE 2(PC)")
p("VZEROUPPER")
p("#endif")
l.save()
p("CALL ·asyncPreempt2(SB)")
l.restore()
p("ADJSP $%d", -l.stack)
p("POPFQ")
p("POPQ BP")
p("RET")
}
func genARM() {
// Add integer registers R0-R12.
// R13 (SP), R14 (LR), R15 (PC) are special and not saved here.
var l = layout{sp: "R13", stack: 4} // add LR slot
for i := 0; i <= 12; i++ {
reg := fmt.Sprintf("R%d", i)
if i == 10 {
continue // R10 is g register, no need to save/restore
}
l.add("MOVW", reg, 4)
}
// Add flag register.
l.addSpecial(
"MOVW CPSR, R0\nMOVW R0, %d(R13)",
"MOVW %d(R13), R0\nMOVW R0, CPSR",
4)
// Add floating point registers F0-F15 and flag register.
var lfp = layout{stack: l.stack, sp: "R13"}
lfp.addSpecial(
"MOVW FPCR, R0\nMOVW R0, %d(R13)",
"MOVW %d(R13), R0\nMOVW R0, FPCR",
4)
for i := 0; i <= 15; i++ {
reg := fmt.Sprintf("F%d", i)
lfp.add("MOVD", reg, 8)
}
p("MOVW.W R14, -%d(R13)", lfp.stack) // allocate frame, save LR
l.save()
p("MOVB ·goarm(SB), R0\nCMP $6, R0\nBLT nofp") // test goarm, and skip FP registers if goarm=5.
lfp.save()
label("nofp:")
p("CALL ·asyncPreempt2(SB)")
p("MOVB ·goarm(SB), R0\nCMP $6, R0\nBLT nofp2") // test goarm, and skip FP registers if goarm=5.
lfp.restore()
label("nofp2:")
l.restore()
p("MOVW %d(R13), R14", lfp.stack) // sigctxt.pushCall pushes LR on stack, restore it
p("MOVW.P %d(R13), R15", lfp.stack+4) // load PC, pop frame (including the space pushed by sigctxt.pushCall)
p("UNDEF") // shouldn't get here
}
func genARM64() {
// Add integer registers R0-R26
// R27 (REGTMP), R28 (g), R29 (FP), R30 (LR), R31 (SP) are special
// and not saved here.
var l = layout{sp: "RSP", stack: 8} // add slot to save PC of interrupted instruction
for i := 0; i <= 26; i++ {
if i == 18 {
continue // R18 is not used, skip
}
reg := fmt.Sprintf("R%d", i)
l.add("MOVD", reg, 8)
}
// Add flag registers.
l.addSpecial(
"MOVD NZCV, R0\nMOVD R0, %d(RSP)",
"MOVD %d(RSP), R0\nMOVD R0, NZCV",
8)
l.addSpecial(
"MOVD FPSR, R0\nMOVD R0, %d(RSP)",
"MOVD %d(RSP), R0\nMOVD R0, FPSR",
8)
// TODO: FPCR? I don't think we'll change it, so no need to save.
// Add floating point registers F0-F31.
for i := 0; i <= 31; i++ {
reg := fmt.Sprintf("F%d", i)
l.add("FMOVD", reg, 8)
}
if l.stack%16 != 0 {
l.stack += 8 // SP needs 16-byte alignment
}
// allocate frame, save PC of interrupted instruction (in LR)
p("MOVD R30, %d(RSP)", -l.stack)
p("SUB $%d, RSP", l.stack)
p("#ifdef GOOS_linux")
p("MOVD R29, -8(RSP)") // save frame pointer (only used on Linux)
p("SUB $8, RSP, R29") // set up new frame pointer
p("#endif")
// On iOS, save the LR again after decrementing SP. We run the
// signal handler on the G stack (as it doesn't support sigaltstack),
// so any writes below SP may be clobbered.
p("#ifdef GOOS_ios")
p("MOVD R30, (RSP)")
p("#endif")
l.save()
p("CALL ·asyncPreempt2(SB)")
l.restore()
p("MOVD %d(RSP), R30", l.stack) // sigctxt.pushCall has pushed LR (at interrupt) on stack, restore it
p("#ifdef GOOS_linux")
p("MOVD -8(RSP), R29") // restore frame pointer
p("#endif")
p("MOVD (RSP), R27") // load PC to REGTMP
p("ADD $%d, RSP", l.stack+16) // pop frame (including the space pushed by sigctxt.pushCall)
p("JMP (R27)")
}
func genMIPS(_64bit bool) {
mov := "MOVW"
movf := "MOVF"
add := "ADD"
sub := "SUB"
r28 := "R28"
regsize := 4
softfloat := "GOMIPS_softfloat"
if _64bit {
mov = "MOVV"
movf = "MOVD"
add = "ADDV"
sub = "SUBV"
r28 = "RSB"
regsize = 8
softfloat = "GOMIPS64_softfloat"
}
// Add integer registers R1-R22, R24-R25, R28
// R0 (zero), R23 (REGTMP), R29 (SP), R30 (g), R31 (LR) are special,
// and not saved here. R26 and R27 are reserved by kernel and not used.
var l = layout{sp: "R29", stack: regsize} // add slot to save PC of interrupted instruction (in LR)
for i := 1; i <= 25; i++ {
if i == 23 {
continue // R23 is REGTMP
}
reg := fmt.Sprintf("R%d", i)
l.add(mov, reg, regsize)
}
l.add(mov, r28, regsize)
l.addSpecial(
mov+" HI, R1\n"+mov+" R1, %d(R29)",
mov+" %d(R29), R1\n"+mov+" R1, HI",
regsize)
l.addSpecial(
mov+" LO, R1\n"+mov+" R1, %d(R29)",
mov+" %d(R29), R1\n"+mov+" R1, LO",
regsize)
// Add floating point control/status register FCR31 (FCR0-FCR30 are irrelevant)
var lfp = layout{sp: "R29", stack: l.stack}
lfp.addSpecial(
mov+" FCR31, R1\n"+mov+" R1, %d(R29)",
mov+" %d(R29), R1\n"+mov+" R1, FCR31",
regsize)
// Add floating point registers F0-F31.
for i := 0; i <= 31; i++ {
reg := fmt.Sprintf("F%d", i)
lfp.add(movf, reg, regsize)
}
// allocate frame, save PC of interrupted instruction (in LR)
p(mov+" R31, -%d(R29)", lfp.stack)
p(sub+" $%d, R29", lfp.stack)
l.save()
p("#ifndef %s", softfloat)
lfp.save()
p("#endif")
p("CALL ·asyncPreempt2(SB)")
p("#ifndef %s", softfloat)
lfp.restore()
p("#endif")
l.restore()
p(mov+" %d(R29), R31", lfp.stack) // sigctxt.pushCall has pushed LR (at interrupt) on stack, restore it
p(mov + " (R29), R23") // load PC to REGTMP
p(add+" $%d, R29", lfp.stack+regsize) // pop frame (including the space pushed by sigctxt.pushCall)
p("JMP (R23)")
}
func genPPC64() {
// Add integer registers R3-R29
// R0 (zero), R1 (SP), R30 (g) are special and not saved here.
// R2 (TOC pointer in PIC mode), R12 (function entry address in PIC mode) have been saved in sigctxt.pushCall.
// R31 (REGTMP) will be saved manually.
var l = layout{sp: "R1", stack: 32 + 8} // MinFrameSize on PPC64, plus one word for saving R31
for i := 3; i <= 29; i++ {
if i == 12 || i == 13 {
// R12 has been saved in sigctxt.pushCall.
// R13 is TLS pointer, not used by Go code. we must NOT
// restore it, otherwise if we parked and resumed on a
// different thread we'll mess up TLS addresses.
continue
}
reg := fmt.Sprintf("R%d", i)
l.add("MOVD", reg, 8)
}
l.addSpecial(
"MOVW CR, R31\nMOVW R31, %d(R1)",
"MOVW %d(R1), R31\nMOVFL R31, $0xff", // this is MOVW R31, CR
8) // CR is 4-byte wide, but just keep the alignment
l.addSpecial(
"MOVD XER, R31\nMOVD R31, %d(R1)",
"MOVD %d(R1), R31\nMOVD R31, XER",
8)
// Add floating point registers F0-F31.
for i := 0; i <= 31; i++ {
reg := fmt.Sprintf("F%d", i)
l.add("FMOVD", reg, 8)
}
// Add floating point control/status register FPSCR.
l.addSpecial(
"MOVFL FPSCR, F0\nFMOVD F0, %d(R1)",
"FMOVD %d(R1), F0\nMOVFL F0, FPSCR",
8)
p("MOVD R31, -%d(R1)", l.stack-32) // save R31 first, we'll use R31 for saving LR
p("MOVD LR, R31")
p("MOVDU R31, -%d(R1)", l.stack) // allocate frame, save PC of interrupted instruction (in LR)
l.save()
p("CALL ·asyncPreempt2(SB)")
l.restore()
p("MOVD %d(R1), R31", l.stack) // sigctxt.pushCall has pushed LR, R2, R12 (at interrupt) on stack, restore them
p("MOVD R31, LR")
p("MOVD %d(R1), R2", l.stack+8)
p("MOVD %d(R1), R12", l.stack+16)
p("MOVD (R1), R31") // load PC to CTR
p("MOVD R31, CTR")
p("MOVD 32(R1), R31") // restore R31
p("ADD $%d, R1", l.stack+32) // pop frame (including the space pushed by sigctxt.pushCall)
p("JMP (CTR)")
}
func genRISCV() {
p("// No async preemption on riscv - see issue 36711")
p("UNDEF")
}
func genRISCV64() {
// X0 (zero), X1 (LR), X2 (SP), X4 (TP), X27 (g), X31 (TMP) are special.
var l = layout{sp: "X2", stack: 8}
// Add integer registers (X3, X5-X26, X28-30).
for i := 3; i < 31; i++ {
if i == 4 || i == 27 {
continue
}
reg := fmt.Sprintf("X%d", i)
l.add("MOV", reg, 8)
}
// Add floating point registers (F0-F31).
for i := 0; i <= 31; i++ {
reg := fmt.Sprintf("F%d", i)
l.add("MOVD", reg, 8)
}
p("MOV X1, -%d(X2)", l.stack)
p("ADD $-%d, X2", l.stack)
l.save()
p("CALL ·asyncPreempt2(SB)")
l.restore()
p("MOV %d(X2), X1", l.stack)
p("MOV (X2), X31")
p("ADD $%d, X2", l.stack+8)
p("JMP (X31)")
}
func genS390X() {
// Add integer registers R0-R12
// R13 (g), R14 (LR), R15 (SP) are special, and not saved here.
// Saving R10 (REGTMP) is not necessary, but it is saved anyway.
var l = layout{sp: "R15", stack: 16} // add slot to save PC of interrupted instruction and flags
l.addSpecial(
"STMG R0, R12, %d(R15)",
"LMG %d(R15), R0, R12",
13*8)
// Add floating point registers F0-F31.
for i := 0; i <= 15; i++ {
reg := fmt.Sprintf("F%d", i)
l.add("FMOVD", reg, 8)
}
// allocate frame, save PC of interrupted instruction (in LR) and flags (condition code)
p("IPM R10") // save flags upfront, as ADD will clobber flags
p("MOVD R14, -%d(R15)", l.stack)
p("ADD $-%d, R15", l.stack)
p("MOVW R10, 8(R15)") // save flags
l.save()
p("CALL ·asyncPreempt2(SB)")
l.restore()
p("MOVD %d(R15), R14", l.stack) // sigctxt.pushCall has pushed LR (at interrupt) on stack, restore it
p("ADD $%d, R15", l.stack+8) // pop frame (including the space pushed by sigctxt.pushCall)
p("MOVWZ -%d(R15), R10", l.stack) // load flags to REGTMP
p("TMLH R10, $(3<<12)") // restore flags
p("MOVD -%d(R15), R10", l.stack+8) // load PC to REGTMP
p("JMP (R10)")
}
func genWasm() {
p("// No async preemption on wasm")
p("UNDEF")
}
func notImplemented() {
p("// Not implemented yet")
p("JMP ·abort(SB)")
}