[dev.ssa] Merge remote-tracking branch 'origin/master' into mergebranch

Conflicts:
	src/cmd/compile/internal/gc/racewalk.go
	src/cmd/internal/obj/stack.go
	src/cmd/internal/obj/x86/obj6.go
	src/runtime/stack.go
	test/nilptr3.go
	test/nosplit.go

Change-Id: Ie6053eb1577fd73e8243651f25c0f1fc765ae660

diff --cc misc/cgo/errors/ptr.go
index 0000000000000000000000000000000000000000,7b670be5a7bb10285222022c310a827240a1fba2..b5d68c719b63440d12ee13dc8efaa317c43775e5
mode 000000,100644..100644
--- /dev/null
--- 2/misc/cgo/errors/ptr.go
+++ b/misc/cgo/errors/ptr.go
@@@ -1,0 -1,409 +1,412 @@@
 -      {
 -              // Storing a Go pointer into C memory should fail.
 -              name: "barrier",
 -              c: `#include <stdlib.h>
 -                    char **f1() { return malloc(sizeof(char*)); }
 -                    void f2(char **p) {}`,
 -              body:      `p := C.f1(); *p = new(C.char); C.f2(p)`,
 -              fail:      true,
 -              expensive: true,
 -      },
 -      {
 -              // Storing a Go pointer into C memory by assigning a
 -              // large value should fail.
 -              name: "barrier-struct",
 -              c: `#include <stdlib.h>
 -                    struct s { char *a[10]; };
 -                    struct s *f1() { return malloc(sizeof(struct s)); }
 -                    void f2(struct s *p) {}`,
 -              body:      `p := C.f1(); p.a = [10]*C.char{new(C.char)}; C.f2(p)`,
 -              fail:      true,
 -              expensive: true,
 -      },
 -      {
 -              // Storing a Go pointer into C memory using a slice
 -              // copy should fail.
 -              name: "barrier-slice",
 -              c: `#include <stdlib.h>
 -                    struct s { char *a[10]; };
 -                    struct s *f1() { return malloc(sizeof(struct s)); }
 -                    void f2(struct s *p) {}`,
 -              body:      `p := C.f1(); copy(p.a[:], []*C.char{new(C.char)}); C.f2(p)`,
 -              fail:      true,
 -              expensive: true,
 -      },
 -      {
 -              // A very large value uses a GC program, which is a
 -              // different code path.
 -              name: "barrier-gcprog-array",
 -              c: `#include <stdlib.h>
 -                    struct s { char *a[32769]; };
 -                    struct s *f1() { return malloc(sizeof(struct s)); }
 -                    void f2(struct s *p) {}`,
 -              body:      `p := C.f1(); p.a = [32769]*C.char{new(C.char)}; C.f2(p)`,
 -              fail:      true,
 -              expensive: true,
 -      },
 -      {
 -              // Similar case, with a source on the heap.
 -              name: "barrier-gcprog-array-heap",
 -              c: `#include <stdlib.h>
 -                    struct s { char *a[32769]; };
 -                    struct s *f1() { return malloc(sizeof(struct s)); }
 -                    void f2(struct s *p) {}
 -                    void f3(void *p) {}`,
 -              imports:   []string{"unsafe"},
 -              body:      `p := C.f1(); n := &[32769]*C.char{new(C.char)}; p.a = *n; C.f2(p); n[0] = nil; C.f3(unsafe.Pointer(n))`,
 -              fail:      true,
 -              expensive: true,
 -      },
 -      {
 -              // A GC program with a struct.
 -              name: "barrier-gcprog-struct",
 -              c: `#include <stdlib.h>
 -                    struct s { char *a[32769]; };
 -                    struct s2 { struct s f; };
 -                    struct s2 *f1() { return malloc(sizeof(struct s2)); }
 -                    void f2(struct s2 *p) {}`,
 -              body:      `p := C.f1(); p.f = C.struct_s{[32769]*C.char{new(C.char)}}; C.f2(p)`,
 -              fail:      true,
 -              expensive: true,
 -      },
 -      {
 -              // Similar case, with a source on the heap.
 -              name: "barrier-gcprog-struct-heap",
 -              c: `#include <stdlib.h>
 -                    struct s { char *a[32769]; };
 -                    struct s2 { struct s f; };
 -                    struct s2 *f1() { return malloc(sizeof(struct s2)); }
 -                    void f2(struct s2 *p) {}
 -                    void f3(void *p) {}`,
 -              imports:   []string{"unsafe"},
 -              body:      `p := C.f1(); n := &C.struct_s{[32769]*C.char{new(C.char)}}; p.f = *n; C.f2(p); n.a[0] = nil; C.f3(unsafe.Pointer(n))`,
 -              fail:      true,
 -              expensive: true,
 -      },
+ // Copyright 2015 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.
+ 
+ // Tests that cgo detects invalid pointer passing at runtime.
+ 
+ package main
+ 
+ import (
+       "bufio"
+       "bytes"
+       "fmt"
+       "io"
+       "io/ioutil"
+       "os"
+       "os/exec"
+       "path/filepath"
+       "runtime"
+       "strings"
+       "sync"
+ )
+ 
+ // ptrTest is the tests without the boilerplate.
+ type ptrTest struct {
+       name      string   // for reporting
+       c         string   // the cgo comment
+       imports   []string // a list of imports
+       support   string   // supporting functions
+       body      string   // the body of the main function
+       fail      bool     // whether the test should fail
+       expensive bool     // whether the test requires the expensive check
+ }
+ 
+ var ptrTests = []ptrTest{
+       {
+               // Passing a pointer to a struct that contains a Go pointer.
+               name: "ptr1",
+               c:    `typedef struct s { int *p; } s; void f(s *ps) {}`,
+               body: `C.f(&C.s{new(C.int)})`,
+               fail: true,
+       },
+       {
+               // Passing a pointer to a struct that contains a Go pointer.
+               name: "ptr2",
+               c:    `typedef struct s { int *p; } s; void f(s *ps) {}`,
+               body: `p := &C.s{new(C.int)}; C.f(p)`,
+               fail: true,
+       },
+       {
+               // Passing a pointer to an int field of a Go struct
+               // that (irrelevantly) contains a Go pointer.
+               name: "ok1",
+               c:    `struct s { int i; int *p; }; void f(int *p) {}`,
+               body: `p := &C.struct_s{i: 0, p: new(C.int)}; C.f(&p.i)`,
+               fail: false,
+       },
+       {
+               // Passing a pointer to a pointer field of a Go struct.
+               name: "ptr-field",
+               c:    `struct s { int i; int *p; }; void f(int **p) {}`,
+               body: `p := &C.struct_s{i: 0, p: new(C.int)}; C.f(&p.p)`,
+               fail: true,
+       },
+       {
+               // Passing a pointer to a pointer field of a Go
+               // struct, where the field does not contain a Go
+               // pointer, but another field (irrelevantly) does.
+               name: "ptr-field-ok",
+               c:    `struct s { int *p1; int *p2; }; void f(int **p) {}`,
+               body: `p := &C.struct_s{p1: nil, p2: new(C.int)}; C.f(&p.p1)`,
+               fail: false,
+       },
+       {
+               // Passing the address of a slice with no Go pointers.
+               name:    "slice-ok-1",
+               c:       `void f(void **p) {}`,
+               imports: []string{"unsafe"},
+               body:    `s := []unsafe.Pointer{nil}; C.f(&s[0])`,
+               fail:    false,
+       },
+       {
+               // Passing the address of a slice with a Go pointer.
+               name:    "slice-ptr-1",
+               c:       `void f(void **p) {}`,
+               imports: []string{"unsafe"},
+               body:    `i := 0; s := []unsafe.Pointer{unsafe.Pointer(&i)}; C.f(&s[0])`,
+               fail:    true,
+       },
+       {
+               // Passing the address of a slice with a Go pointer,
+               // where we are passing the address of an element that
+               // is not a Go pointer.
+               name:    "slice-ptr-2",
+               c:       `void f(void **p) {}`,
+               imports: []string{"unsafe"},
+               body:    `i := 0; s := []unsafe.Pointer{nil, unsafe.Pointer(&i)}; C.f(&s[0])`,
+               fail:    true,
+       },
+       {
+               // Passing the address of a slice that is an element
+               // in a struct only looks at the slice.
+               name:    "slice-ok-2",
+               c:       `void f(void **p) {}`,
+               imports: []string{"unsafe"},
+               support: `type S struct { p *int; s []unsafe.Pointer }`,
+               body:    `i := 0; p := &S{p:&i, s:[]unsafe.Pointer{nil}}; C.f(&p.s[0])`,
+               fail:    false,
+       },
+       {
+               // Passing the address of a static variable with no
+               // pointers doesn't matter.
+               name:    "varok",
+               c:       `void f(char** parg) {}`,
+               support: `var hello = [...]C.char{'h', 'e', 'l', 'l', 'o'}`,
+               body:    `parg := [1]*C.char{&hello[0]}; C.f(&parg[0])`,
+               fail:    false,
+       },
+       {
+               // Passing the address of a static variable with
+               // pointers does matter.
+               name:    "var",
+               c:       `void f(char*** parg) {}`,
+               support: `var hello = [...]*C.char{new(C.char)}`,
+               body:    `parg := [1]**C.char{&hello[0]}; C.f(&parg[0])`,
+               fail:    true,
+       },
++      /*
++              TODO(khr): reenable when write barriers are fixed.
++                      {
++                              // Storing a Go pointer into C memory should fail.
++                              name: "barrier",
++                              c: `#include <stdlib.h>
++                                  char **f1() { return malloc(sizeof(char*)); }
++                                  void f2(char **p) {}`,
++                              body:      `p := C.f1(); *p = new(C.char); C.f2(p)`,
++                              fail:      true,
++                              expensive: true,
++                      },
++                      {
++                              // Storing a Go pointer into C memory by assigning a
++                              // large value should fail.
++                              name: "barrier-struct",
++                              c: `#include <stdlib.h>
++                                  struct s { char *a[10]; };
++                                  struct s *f1() { return malloc(sizeof(struct s)); }
++                                  void f2(struct s *p) {}`,
++                              body:      `p := C.f1(); p.a = [10]*C.char{new(C.char)}; C.f2(p)`,
++                              fail:      true,
++                              expensive: true,
++                      },
++                      {
++                              // Storing a Go pointer into C memory using a slice
++                              // copy should fail.
++                              name: "barrier-slice",
++                              c: `#include <stdlib.h>
++                                  struct s { char *a[10]; };
++                                  struct s *f1() { return malloc(sizeof(struct s)); }
++                                  void f2(struct s *p) {}`,
++                              body:      `p := C.f1(); copy(p.a[:], []*C.char{new(C.char)}); C.f2(p)`,
++                              fail:      true,
++                              expensive: true,
++                      },
++                      {
++                              // A very large value uses a GC program, which is a
++                              // different code path.
++                              name: "barrier-gcprog-array",
++                              c: `#include <stdlib.h>
++                                  struct s { char *a[32769]; };
++                                  struct s *f1() { return malloc(sizeof(struct s)); }
++                                  void f2(struct s *p) {}`,
++                              body:      `p := C.f1(); p.a = [32769]*C.char{new(C.char)}; C.f2(p)`,
++                              fail:      true,
++                              expensive: true,
++                      },
++                      {
++                              // Similar case, with a source on the heap.
++                              name: "barrier-gcprog-array-heap",
++                              c: `#include <stdlib.h>
++                                  struct s { char *a[32769]; };
++                                  struct s *f1() { return malloc(sizeof(struct s)); }
++                                  void f2(struct s *p) {}
++                                  void f3(void *p) {}`,
++                              imports:   []string{"unsafe"},
++                              body:      `p := C.f1(); n := &[32769]*C.char{new(C.char)}; p.a = *n; C.f2(p); n[0] = nil; C.f3(unsafe.Pointer(n))`,
++                              fail:      true,
++                              expensive: true,
++                      },
++                      {
++                              // A GC program with a struct.
++                              name: "barrier-gcprog-struct",
++                              c: `#include <stdlib.h>
++                                  struct s { char *a[32769]; };
++                                  struct s2 { struct s f; };
++                                  struct s2 *f1() { return malloc(sizeof(struct s2)); }
++                                  void f2(struct s2 *p) {}`,
++                              body:      `p := C.f1(); p.f = C.struct_s{[32769]*C.char{new(C.char)}}; C.f2(p)`,
++                              fail:      true,
++                              expensive: true,
++                      },
++                      {
++                              // Similar case, with a source on the heap.
++                              name: "barrier-gcprog-struct-heap",
++                              c: `#include <stdlib.h>
++                                  struct s { char *a[32769]; };
++                                  struct s2 { struct s f; };
++                                  struct s2 *f1() { return malloc(sizeof(struct s2)); }
++                                  void f2(struct s2 *p) {}
++                                  void f3(void *p) {}`,
++                              imports:   []string{"unsafe"},
++                              body:      `p := C.f1(); n := &C.struct_s{[32769]*C.char{new(C.char)}}; p.f = *n; C.f2(p); n.a[0] = nil; C.f3(unsafe.Pointer(n))`,
++                              fail:      true,
++                              expensive: true,
++                      },
++      */
+ }
+ 
+ func main() {
+       os.Exit(doTests())
+ }
+ 
+ func doTests() int {
+       dir, err := ioutil.TempDir("", "cgoerrors")
+       if err != nil {
+               fmt.Fprintln(os.Stderr, err)
+               return 2
+       }
+       defer os.RemoveAll(dir)
+ 
+       workers := runtime.NumCPU() + 1
+ 
+       var wg sync.WaitGroup
+       c := make(chan int)
+       errs := make(chan int)
+       for i := 0; i < workers; i++ {
+               wg.Add(1)
+               go func() {
+                       worker(dir, c, errs)
+                       wg.Done()
+               }()
+       }
+ 
+       for i := range ptrTests {
+               c <- i
+       }
+       close(c)
+ 
+       go func() {
+               wg.Wait()
+               close(errs)
+       }()
+ 
+       tot := 0
+       for e := range errs {
+               tot += e
+       }
+       return tot
+ }
+ 
+ func worker(dir string, c, errs chan int) {
+       e := 0
+       for i := range c {
+               if !doOne(dir, i) {
+                       e++
+               }
+       }
+       if e > 0 {
+               errs <- e
+       }
+ }
+ 
+ func doOne(dir string, i int) bool {
+       t := &ptrTests[i]
+ 
+       name := filepath.Join(dir, fmt.Sprintf("t%d.go", i))
+       f, err := os.Create(name)
+       if err != nil {
+               fmt.Fprintln(os.Stderr, err)
+               return false
+       }
+ 
+       b := bufio.NewWriter(f)
+       fmt.Fprintln(b, `package main`)
+       fmt.Fprintln(b)
+       fmt.Fprintln(b, `/*`)
+       fmt.Fprintln(b, t.c)
+       fmt.Fprintln(b, `*/`)
+       fmt.Fprintln(b, `import "C"`)
+       fmt.Fprintln(b)
+       for _, imp := range t.imports {
+               fmt.Fprintln(b, `import "`+imp+`"`)
+       }
+       if len(t.imports) > 0 {
+               fmt.Fprintln(b)
+       }
+       if len(t.support) > 0 {
+               fmt.Fprintln(b, t.support)
+               fmt.Fprintln(b)
+       }
+       fmt.Fprintln(b, `func main() {`)
+       fmt.Fprintln(b, t.body)
+       fmt.Fprintln(b, `}`)
+ 
+       if err := b.Flush(); err != nil {
+               fmt.Fprintf(os.Stderr, "flushing %s: %v\n", name, err)
+               return false
+       }
+       if err := f.Close(); err != nil {
+               fmt.Fprintln(os.Stderr, "closing %s: %v\n", name, err)
+               return false
+       }
+ 
+       ok := true
+ 
+       cmd := exec.Command("go", "run", name)
+       cmd.Dir = dir
+ 
+       if t.expensive {
+               cmd.Env = cgocheckEnv("1")
+               buf, err := cmd.CombinedOutput()
+               if err != nil {
+                       var errbuf bytes.Buffer
+                       if t.fail {
+                               fmt.Fprintf(&errbuf, "test %s marked expensive but failed when not expensive: %v\n", t.name, err)
+                       } else {
+                               fmt.Fprintf(&errbuf, "test %s failed unexpectedly with GODEBUG=cgocheck=1: %v\n", t.name, err)
+                       }
+                       reportTestOutput(&errbuf, t.name, buf)
+                       os.Stderr.Write(errbuf.Bytes())
+                       ok = false
+               }
+ 
+               cmd = exec.Command("go", "run", name)
+               cmd.Dir = dir
+       }
+ 
+       if t.expensive {
+               cmd.Env = cgocheckEnv("2")
+       }
+ 
+       buf, err := cmd.CombinedOutput()
+ 
+       if t.fail {
+               if err == nil {
+                       var errbuf bytes.Buffer
+                       fmt.Fprintf(&errbuf, "test %s did not fail as expected\n", t.name)
+                       reportTestOutput(&errbuf, t.name, buf)
+                       os.Stderr.Write(errbuf.Bytes())
+                       ok = false
+               } else if !bytes.Contains(buf, []byte("Go pointer")) {
+                       var errbuf bytes.Buffer
+                       fmt.Fprintf(&errbuf, "test %s output does not contain expected error (failed with %v)\n", t.name, err)
+                       reportTestOutput(&errbuf, t.name, buf)
+                       os.Stderr.Write(errbuf.Bytes())
+                       ok = false
+               }
+       } else {
+               if err != nil {
+                       var errbuf bytes.Buffer
+                       fmt.Fprintf(&errbuf, "test %s failed unexpectedly: %v\n", t.name, err)
+                       reportTestOutput(&errbuf, t.name, buf)
+                       os.Stderr.Write(errbuf.Bytes())
+                       ok = false
+               }
+ 
+               if !t.expensive && ok {
+                       // Make sure it passes with the expensive checks.
+                       cmd := exec.Command("go", "run", name)
+                       cmd.Dir = dir
+                       cmd.Env = cgocheckEnv("2")
+                       buf, err := cmd.CombinedOutput()
+                       if err != nil {
+                               var errbuf bytes.Buffer
+                               fmt.Fprintf(&errbuf, "test %s failed unexpectedly with expensive checks: %v\n", t.name, err)
+                               reportTestOutput(&errbuf, t.name, buf)
+                               os.Stderr.Write(errbuf.Bytes())
+                               ok = false
+                       }
+               }
+       }
+ 
+       if t.fail && ok {
+               cmd = exec.Command("go", "run", name)
+               cmd.Dir = dir
+               cmd.Env = cgocheckEnv("0")
+               buf, err := cmd.CombinedOutput()
+               if err != nil {
+                       var errbuf bytes.Buffer
+                       fmt.Fprintf(&errbuf, "test %s failed unexpectedly with GODEBUG=cgocheck=0: %v\n", t.name, err)
+                       reportTestOutput(&errbuf, t.name, buf)
+                       os.Stderr.Write(errbuf.Bytes())
+                       ok = false
+               }
+       }
+ 
+       return ok
+ }
+ 
+ func reportTestOutput(w io.Writer, name string, buf []byte) {
+       fmt.Fprintf(w, "=== test %s output ===\n", name)
+       fmt.Fprintf(w, "%s", buf)
+       fmt.Fprintf(w, "=== end of test %s output ===\n", name)
+ }
+ 
+ func cgocheckEnv(val string) []string {
+       env := []string{"GODEBUG=cgocheck=" + val}
+       for _, e := range os.Environ() {
+               if !strings.HasPrefix(e, "GODEBUG=") {
+                       env = append(env, e)
+               }
+       }
+       return env
+ }

diff --cc src/cmd/compile/internal/amd64/prog.go
Simple merge

diff --cc src/cmd/compile/internal/gc/builtin.go
Simple merge

diff --cc src/cmd/compile/internal/gc/builtin/runtime.go
Simple merge

diff --cc src/cmd/compile/internal/gc/closure.go
Simple merge

diff --cc src/cmd/compile/internal/gc/fmt.go
Simple merge

diff --cc src/cmd/compile/internal/gc/gen.go
Simple merge

diff --cc src/cmd/compile/internal/gc/go.go
Simple merge

diff --cc src/cmd/compile/internal/gc/gsubr.go
Simple merge

diff --cc src/cmd/compile/internal/gc/pgen.go
Simple merge

diff --cc src/cmd/compile/internal/gc/plive.go
Simple merge

diff --cc src/cmd/compile/internal/gc/racewalk.go
index f127dfd0d0597683566f53960a0e549ef8ff44c2,35e06b9e7eefdeea5f467ad70965e954f23221dd..1f9e167748000e43a8fa80bff4943f9d27d1b050
--- 1/src/cmd/compile/internal/gc/racewalk.go
--- 2/src/cmd/compile/internal/gc/racewalk.go
+++ b/src/cmd/compile/internal/gc/racewalk.go
@@@ -9,9 -9,11 +9,11 @@@ import 
        "strings"
  )
  
- // The racewalk pass modifies the code tree for the function as follows:
+ // The instrument pass modifies the code tree for instrumentation.
+ //
+ // For flag_race it modifies the function as follows:
  //
 -// 1. It inserts a call to racefuncenter at the beginning of each function.
 +// 1. It inserts a call to racefuncenterfp at the beginning of each function.
  // 2. It inserts a call to racefuncexit at the end of each function.
  // 3. It inserts a call to raceread before each memory read.
  // 4. It inserts a call to racewrite before each memory write.
@@@ -24,11 -31,11 +31,11 @@@
  
  // Do not instrument the following packages at all,
  // at best instrumentation would cause infinite recursion.
- var omit_pkgs = []string{"runtime", "runtime/race"}
+ var omit_pkgs = []string{"runtime/internal/atomic", "runtime/internal/sys", "runtime", "runtime/race", "runtime/msan"}
  
 -// Only insert racefuncenter/racefuncexit into the following packages.
 +// Only insert racefuncenterfp/racefuncexit into the following packages.
  // Memory accesses in the packages are either uninteresting or will cause false positives.
- var noinst_pkgs = []string{"sync", "sync/atomic"}
+ var norace_inst_pkgs = []string{"sync", "sync/atomic"}
  
  func ispkgin(pkgs []string) bool {
        if myimportpath != "" {

diff --cc src/cmd/compile/internal/gc/sinit.go
Simple merge

diff --cc src/cmd/compile/internal/gc/ssa.go
index 4cdfa5c265054c7145f588f2ed015d7e7987b399,0000000000000000000000000000000000000000..4604fa682eb86f9980808568c39bd1e426e116b2
mode 100644,000000..100644
--- 1/src/cmd/compile/internal/gc/ssa.go
--- /dev/null
+++ b/src/cmd/compile/internal/gc/ssa.go
@@@ -1,4610 -1,0 +1,4612 @@@
-       // nodfp is a special argument which is the function's FP.
-       aux := &ssa.ArgSymbol{Typ: Types[TUINTPTR], Node: nodfp}
-       s.decladdrs[nodfp] = s.entryNewValue1A(ssa.OpAddr, Types[TUINTPTR], aux, s.sp)
 +// Copyright 2015 The Go Authors. All rights reserved.
 +// Use of this source code is governed by a BSD-style
 +// license that can be found in the LICENSE file.
 +
 +package gc
 +
 +import (
 +      "bytes"
 +      "crypto/sha1"
 +      "fmt"
 +      "html"
 +      "math"
 +      "os"
 +      "strings"
 +
 +      "cmd/compile/internal/ssa"
 +      "cmd/internal/obj"
 +      "cmd/internal/obj/x86"
 +)
 +
 +// Smallest possible faulting page at address zero.
 +const minZeroPage = 4096
 +
 +// buildssa builds an SSA function
 +// and reports whether it should be used.
 +// Once the SSA implementation is complete,
 +// it will never return nil, and the bool can be removed.
 +func buildssa(fn *Node) (ssafn *ssa.Func, usessa bool) {
 +      name := fn.Func.Nname.Sym.Name
 +      gossahash := os.Getenv("GOSSAHASH")
 +      usessa = strings.HasSuffix(name, "_ssa") || strings.Contains(name, "_ssa.") || name == os.Getenv("GOSSAFUNC")
 +
 +      // Environment variable control of SSA CG
 +      // 1. IF GOSSAFUNC == current function name THEN
 +      //       compile this function with SSA and log output to ssa.html
 +
 +      // 2. IF GOSSAHASH == "" THEN
 +      //       compile this function (and everything else) with SSA
 +
 +      // 3. IF GOSSAHASH == "n" or "N"
 +      //       IF GOSSAPKG == current package name THEN
 +      //          compile this function (and everything in this package) with SSA
 +      //       ELSE
 +      //          use the old back end for this function.
 +      //       This is for compatibility with existing test harness and should go away.
 +
 +      // 4. IF GOSSAHASH is a suffix of the binary-rendered SHA1 hash of the function name THEN
 +      //          compile this function with SSA
 +      //       ELSE
 +      //          compile this function with the old back end.
 +
 +      // Plan is for 3 to be removed when the tests are revised.
 +      // SSA is now default, and is disabled by setting
 +      // GOSSAHASH to n or N, or selectively with strings of
 +      // 0 and 1.
 +
 +      if usessa {
 +              fmt.Println("generating SSA for", name)
 +              dumplist("buildssa-enter", fn.Func.Enter)
 +              dumplist("buildssa-body", fn.Nbody)
 +              dumplist("buildssa-exit", fn.Func.Exit)
 +      }
 +
 +      var s state
 +      s.pushLine(fn.Lineno)
 +      defer s.popLine()
 +
 +      // TODO(khr): build config just once at the start of the compiler binary
 +
 +      var e ssaExport
 +      e.log = usessa
 +      s.config = ssa.NewConfig(Thearch.Thestring, &e, Ctxt)
 +      s.f = s.config.NewFunc()
 +      s.f.Name = name
 +      s.exitCode = fn.Func.Exit
 +      s.panics = map[funcLine]*ssa.Block{}
 +
 +      if name == os.Getenv("GOSSAFUNC") {
 +              // TODO: tempfile? it is handy to have the location
 +              // of this file be stable, so you can just reload in the browser.
 +              s.config.HTML = ssa.NewHTMLWriter("ssa.html", &s, name)
 +              // TODO: generate and print a mapping from nodes to values and blocks
 +      }
 +      defer func() {
 +              if !usessa {
 +                      s.config.HTML.Close()
 +              }
 +      }()
 +
 +      // We construct SSA using an algorithm similar to
 +      // Brau, Buchwald, Hack, Leißa, Mallon, and Zwinkau
 +      // http://pp.info.uni-karlsruhe.de/uploads/publikationen/braun13cc.pdf
 +      // TODO: check this comment
 +
 +      // Allocate starting block
 +      s.f.Entry = s.f.NewBlock(ssa.BlockPlain)
 +
 +      // Allocate starting values
 +      s.labels = map[string]*ssaLabel{}
 +      s.labeledNodes = map[*Node]*ssaLabel{}
 +      s.startmem = s.entryNewValue0(ssa.OpInitMem, ssa.TypeMem)
 +      s.sp = s.entryNewValue0(ssa.OpSP, Types[TUINTPTR]) // TODO: use generic pointer type (unsafe.Pointer?) instead
 +      s.sb = s.entryNewValue0(ssa.OpSB, Types[TUINTPTR])
 +
 +      s.startBlock(s.f.Entry)
 +      s.vars[&memVar] = s.startmem
 +
 +      s.varsyms = map[*Node]interface{}{}
 +
 +      // Generate addresses of local declarations
 +      s.decladdrs = map[*Node]*ssa.Value{}
 +      for d := fn.Func.Dcl; d != nil; d = d.Next {
 +              n := d.N
 +              switch n.Class {
 +              case PPARAM:
 +                      aux := s.lookupSymbol(n, &ssa.ArgSymbol{Typ: n.Type, Node: n})
 +                      s.decladdrs[n] = s.entryNewValue1A(ssa.OpAddr, Ptrto(n.Type), aux, s.sp)
 +              case PAUTO | PHEAP:
 +                      // TODO this looks wrong for PAUTO|PHEAP, no vardef, but also no definition
 +                      aux := s.lookupSymbol(n, &ssa.AutoSymbol{Typ: n.Type, Node: n})
 +                      s.decladdrs[n] = s.entryNewValue1A(ssa.OpAddr, Ptrto(n.Type), aux, s.sp)
 +              case PPARAM | PHEAP, PPARAMOUT | PHEAP:
 +              // This ends up wrong, have to do it at the PARAM node instead.
 +              case PAUTO, PPARAMOUT:
 +                      // processed at each use, to prevent Addr coming
 +                      // before the decl.
 +              case PFUNC:
 +                      // local function - already handled by frontend
 +              default:
 +                      str := ""
 +                      if n.Class&PHEAP != 0 {
 +                              str = ",heap"
 +                      }
 +                      s.Unimplementedf("local variable with class %s%s unimplemented", classnames[n.Class&^PHEAP], str)
 +              }
 +      }
-       op    uint8
-       etype uint8
 +
 +      // Convert the AST-based IR to the SSA-based IR
 +      s.stmtList(fn.Func.Enter)
 +      s.stmtList(fn.Nbody)
 +
 +      // fallthrough to exit
 +      if s.curBlock != nil {
 +              s.stmtList(s.exitCode)
 +              m := s.mem()
 +              b := s.endBlock()
 +              b.Kind = ssa.BlockRet
 +              b.Control = m
 +      }
 +
 +      // Check that we used all labels
 +      for name, lab := range s.labels {
 +              if !lab.used() && !lab.reported {
 +                      yyerrorl(int(lab.defNode.Lineno), "label %v defined and not used", name)
 +                      lab.reported = true
 +              }
 +              if lab.used() && !lab.defined() && !lab.reported {
 +                      yyerrorl(int(lab.useNode.Lineno), "label %v not defined", name)
 +                      lab.reported = true
 +              }
 +      }
 +
 +      // Check any forward gotos. Non-forward gotos have already been checked.
 +      for _, n := range s.fwdGotos {
 +              lab := s.labels[n.Left.Sym.Name]
 +              // If the label is undefined, we have already have printed an error.
 +              if lab.defined() {
 +                      s.checkgoto(n, lab.defNode)
 +              }
 +      }
 +
 +      if nerrors > 0 {
 +              return nil, false
 +      }
 +
 +      // Link up variable uses to variable definitions
 +      s.linkForwardReferences()
 +
 +      // Don't carry reference this around longer than necessary
 +      s.exitCode = nil
 +
 +      // Main call to ssa package to compile function
 +      ssa.Compile(s.f)
 +
 +      // gossahash = "y" is historical/symmetric-with-"n" -- i.e., not really needed.
 +      if usessa || gossahash == "" || gossahash == "y" || gossahash == "Y" {
 +              return s.f, true
 +      }
 +      if gossahash == "n" || gossahash == "N" {
 +              if localpkg.Name != os.Getenv("GOSSAPKG") {
 +                      return s.f, false
 +              }
 +              // Use everything in the package
 +              return s.f, true
 +      }
 +
 +      // Check the hash of the name against a partial input hash.
 +      // We use this feature to do a binary search within a package to
 +      // find a function that is incorrectly compiled.
 +      hstr := ""
 +      for _, b := range sha1.Sum([]byte(name)) {
 +              hstr += fmt.Sprintf("%08b", b)
 +      }
 +
 +      if strings.HasSuffix(hstr, gossahash) {
 +              fmt.Printf("GOSSAHASH triggered %s\n", name)
 +              return s.f, true
 +      }
 +
 +      // Iteratively try additional hashes to allow tests for multi-point
 +      // failure.
 +      for i := 0; true; i++ {
 +              ev := fmt.Sprintf("GOSSAHASH%d", i)
 +              evv := os.Getenv(ev)
 +              if evv == "" {
 +                      break
 +              }
 +              if strings.HasSuffix(hstr, evv) {
 +                      fmt.Printf("%s triggered %s\n", ev, name)
 +                      return s.f, true
 +              }
 +      }
 +
 +      return s.f, false
 +}
 +
 +type state struct {
 +      // configuration (arch) information
 +      config *ssa.Config
 +
 +      // function we're building
 +      f *ssa.Func
 +
 +      // labels and labeled control flow nodes (OFOR, OSWITCH, OSELECT) in f
 +      labels       map[string]*ssaLabel
 +      labeledNodes map[*Node]*ssaLabel
 +
 +      // gotos that jump forward; required for deferred checkgoto calls
 +      fwdGotos []*Node
 +      // Code that must precede any return
 +      // (e.g., copying value of heap-escaped paramout back to true paramout)
 +      exitCode *NodeList
 +
 +      // unlabeled break and continue statement tracking
 +      breakTo    *ssa.Block // current target for plain break statement
 +      continueTo *ssa.Block // current target for plain continue statement
 +
 +      // current location where we're interpreting the AST
 +      curBlock *ssa.Block
 +
 +      // variable assignments in the current block (map from variable symbol to ssa value)
 +      // *Node is the unique identifier (an ONAME Node) for the variable.
 +      vars map[*Node]*ssa.Value
 +
 +      // all defined variables at the end of each block.  Indexed by block ID.
 +      defvars []map[*Node]*ssa.Value
 +
 +      // addresses of PPARAM and PPARAMOUT variables.
 +      decladdrs map[*Node]*ssa.Value
 +
 +      // symbols for PEXTERN, PAUTO and PPARAMOUT variables so they can be reused.
 +      varsyms map[*Node]interface{}
 +
 +      // starting values.  Memory, stack pointer, and globals pointer
 +      startmem *ssa.Value
 +      sp       *ssa.Value
 +      sb       *ssa.Value
 +
 +      // line number stack.  The current line number is top of stack
 +      line []int32
 +
 +      // list of panic calls by function name and line number.
 +      // Used to deduplicate panic calls.
 +      panics map[funcLine]*ssa.Block
 +}
 +
 +type funcLine struct {
 +      f    *Node
 +      line int32
 +}
 +
 +type ssaLabel struct {
 +      target         *ssa.Block // block identified by this label
 +      breakTarget    *ssa.Block // block to break to in control flow node identified by this label
 +      continueTarget *ssa.Block // block to continue to in control flow node identified by this label
 +      defNode        *Node      // label definition Node (OLABEL)
 +      // Label use Node (OGOTO, OBREAK, OCONTINUE).
 +      // Used only for error detection and reporting.
 +      // There might be multiple uses, but we only need to track one.
 +      useNode  *Node
 +      reported bool // reported indicates whether an error has already been reported for this label
 +}
 +
 +// defined reports whether the label has a definition (OLABEL node).
 +func (l *ssaLabel) defined() bool { return l.defNode != nil }
 +
 +// used reports whether the label has a use (OGOTO, OBREAK, or OCONTINUE node).
 +func (l *ssaLabel) used() bool { return l.useNode != nil }
 +
 +// label returns the label associated with sym, creating it if necessary.
 +func (s *state) label(sym *Sym) *ssaLabel {
 +      lab := s.labels[sym.Name]
 +      if lab == nil {
 +              lab = new(ssaLabel)
 +              s.labels[sym.Name] = lab
 +      }
 +      return lab
 +}
 +
 +func (s *state) Logf(msg string, args ...interface{})            { s.config.Logf(msg, args...) }
 +func (s *state) Fatalf(msg string, args ...interface{})          { s.config.Fatalf(msg, args...) }
 +func (s *state) Unimplementedf(msg string, args ...interface{})  { s.config.Unimplementedf(msg, args...) }
 +func (s *state) Warnl(line int, msg string, args ...interface{}) { s.config.Warnl(line, msg, args...) }
 +func (s *state) Debug_checknil() bool                            { return s.config.Debug_checknil() }
 +
 +var (
 +      // dummy node for the memory variable
 +      memVar = Node{Op: ONAME, Class: Pxxx, Sym: &Sym{Name: "mem"}}
 +
 +      // dummy nodes for temporary variables
 +      ptrVar   = Node{Op: ONAME, Class: Pxxx, Sym: &Sym{Name: "ptr"}}
 +      capVar   = Node{Op: ONAME, Class: Pxxx, Sym: &Sym{Name: "cap"}}
 +      typVar   = Node{Op: ONAME, Class: Pxxx, Sym: &Sym{Name: "typ"}}
 +      idataVar = Node{Op: ONAME, Class: Pxxx, Sym: &Sym{Name: "idata"}}
 +      okVar    = Node{Op: ONAME, Class: Pxxx, Sym: &Sym{Name: "ok"}}
 +)
 +
 +// startBlock sets the current block we're generating code in to b.
 +func (s *state) startBlock(b *ssa.Block) {
 +      if s.curBlock != nil {
 +              s.Fatalf("starting block %v when block %v has not ended", b, s.curBlock)
 +      }
 +      s.curBlock = b
 +      s.vars = map[*Node]*ssa.Value{}
 +}
 +
 +// endBlock marks the end of generating code for the current block.
 +// Returns the (former) current block.  Returns nil if there is no current
 +// block, i.e. if no code flows to the current execution point.
 +func (s *state) endBlock() *ssa.Block {
 +      b := s.curBlock
 +      if b == nil {
 +              return nil
 +      }
 +      for len(s.defvars) <= int(b.ID) {
 +              s.defvars = append(s.defvars, nil)
 +      }
 +      s.defvars[b.ID] = s.vars
 +      s.curBlock = nil
 +      s.vars = nil
 +      b.Line = s.peekLine()
 +      return b
 +}
 +
 +// pushLine pushes a line number on the line number stack.
 +func (s *state) pushLine(line int32) {
 +      s.line = append(s.line, line)
 +}
 +
 +// popLine pops the top of the line number stack.
 +func (s *state) popLine() {
 +      s.line = s.line[:len(s.line)-1]
 +}
 +
 +// peekLine peek the top of the line number stack.
 +func (s *state) peekLine() int32 {
 +      return s.line[len(s.line)-1]
 +}
 +
 +func (s *state) Error(msg string, args ...interface{}) {
 +      yyerrorl(int(s.peekLine()), msg, args...)
 +}
 +
 +// newValue0 adds a new value with no arguments to the current block.
 +func (s *state) newValue0(op ssa.Op, t ssa.Type) *ssa.Value {
 +      return s.curBlock.NewValue0(s.peekLine(), op, t)
 +}
 +
 +// newValue0A adds a new value with no arguments and an aux value to the current block.
 +func (s *state) newValue0A(op ssa.Op, t ssa.Type, aux interface{}) *ssa.Value {
 +      return s.curBlock.NewValue0A(s.peekLine(), op, t, aux)
 +}
 +
 +// newValue0I adds a new value with no arguments and an auxint value to the current block.
 +func (s *state) newValue0I(op ssa.Op, t ssa.Type, auxint int64) *ssa.Value {
 +      return s.curBlock.NewValue0I(s.peekLine(), op, t, auxint)
 +}
 +
 +// newValue1 adds a new value with one argument to the current block.
 +func (s *state) newValue1(op ssa.Op, t ssa.Type, arg *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue1(s.peekLine(), op, t, arg)
 +}
 +
 +// newValue1A adds a new value with one argument and an aux value to the current block.
 +func (s *state) newValue1A(op ssa.Op, t ssa.Type, aux interface{}, arg *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue1A(s.peekLine(), op, t, aux, arg)
 +}
 +
 +// newValue1I adds a new value with one argument and an auxint value to the current block.
 +func (s *state) newValue1I(op ssa.Op, t ssa.Type, aux int64, arg *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue1I(s.peekLine(), op, t, aux, arg)
 +}
 +
 +// newValue2 adds a new value with two arguments to the current block.
 +func (s *state) newValue2(op ssa.Op, t ssa.Type, arg0, arg1 *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue2(s.peekLine(), op, t, arg0, arg1)
 +}
 +
 +// newValue2I adds a new value with two arguments and an auxint value to the current block.
 +func (s *state) newValue2I(op ssa.Op, t ssa.Type, aux int64, arg0, arg1 *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue2I(s.peekLine(), op, t, aux, arg0, arg1)
 +}
 +
 +// newValue3 adds a new value with three arguments to the current block.
 +func (s *state) newValue3(op ssa.Op, t ssa.Type, arg0, arg1, arg2 *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue3(s.peekLine(), op, t, arg0, arg1, arg2)
 +}
 +
 +// newValue3I adds a new value with three arguments and an auxint value to the current block.
 +func (s *state) newValue3I(op ssa.Op, t ssa.Type, aux int64, arg0, arg1, arg2 *ssa.Value) *ssa.Value {
 +      return s.curBlock.NewValue3I(s.peekLine(), op, t, aux, arg0, arg1, arg2)
 +}
 +
 +// entryNewValue0 adds a new value with no arguments to the entry block.
 +func (s *state) entryNewValue0(op ssa.Op, t ssa.Type) *ssa.Value {
 +      return s.f.Entry.NewValue0(s.peekLine(), op, t)
 +}
 +
 +// entryNewValue0A adds a new value with no arguments and an aux value to the entry block.
 +func (s *state) entryNewValue0A(op ssa.Op, t ssa.Type, aux interface{}) *ssa.Value {
 +      return s.f.Entry.NewValue0A(s.peekLine(), op, t, aux)
 +}
 +
 +// entryNewValue0I adds a new value with no arguments and an auxint value to the entry block.
 +func (s *state) entryNewValue0I(op ssa.Op, t ssa.Type, auxint int64) *ssa.Value {
 +      return s.f.Entry.NewValue0I(s.peekLine(), op, t, auxint)
 +}
 +
 +// entryNewValue1 adds a new value with one argument to the entry block.
 +func (s *state) entryNewValue1(op ssa.Op, t ssa.Type, arg *ssa.Value) *ssa.Value {
 +      return s.f.Entry.NewValue1(s.peekLine(), op, t, arg)
 +}
 +
 +// entryNewValue1 adds a new value with one argument and an auxint value to the entry block.
 +func (s *state) entryNewValue1I(op ssa.Op, t ssa.Type, auxint int64, arg *ssa.Value) *ssa.Value {
 +      return s.f.Entry.NewValue1I(s.peekLine(), op, t, auxint, arg)
 +}
 +
 +// entryNewValue1A adds a new value with one argument and an aux value to the entry block.
 +func (s *state) entryNewValue1A(op ssa.Op, t ssa.Type, aux interface{}, arg *ssa.Value) *ssa.Value {
 +      return s.f.Entry.NewValue1A(s.peekLine(), op, t, aux, arg)
 +}
 +
 +// entryNewValue2 adds a new value with two arguments to the entry block.
 +func (s *state) entryNewValue2(op ssa.Op, t ssa.Type, arg0, arg1 *ssa.Value) *ssa.Value {
 +      return s.f.Entry.NewValue2(s.peekLine(), op, t, arg0, arg1)
 +}
 +
 +// const* routines add a new const value to the entry block.
 +func (s *state) constBool(c bool) *ssa.Value {
 +      return s.f.ConstBool(s.peekLine(), Types[TBOOL], c)
 +}
 +func (s *state) constInt8(t ssa.Type, c int8) *ssa.Value {
 +      return s.f.ConstInt8(s.peekLine(), t, c)
 +}
 +func (s *state) constInt16(t ssa.Type, c int16) *ssa.Value {
 +      return s.f.ConstInt16(s.peekLine(), t, c)
 +}
 +func (s *state) constInt32(t ssa.Type, c int32) *ssa.Value {
 +      return s.f.ConstInt32(s.peekLine(), t, c)
 +}
 +func (s *state) constInt64(t ssa.Type, c int64) *ssa.Value {
 +      return s.f.ConstInt64(s.peekLine(), t, c)
 +}
 +func (s *state) constFloat32(t ssa.Type, c float64) *ssa.Value {
 +      return s.f.ConstFloat32(s.peekLine(), t, c)
 +}
 +func (s *state) constFloat64(t ssa.Type, c float64) *ssa.Value {
 +      return s.f.ConstFloat64(s.peekLine(), t, c)
 +}
 +func (s *state) constInt(t ssa.Type, c int64) *ssa.Value {
 +      if s.config.IntSize == 8 {
 +              return s.constInt64(t, c)
 +      }
 +      if int64(int32(c)) != c {
 +              s.Fatalf("integer constant too big %d", c)
 +      }
 +      return s.constInt32(t, int32(c))
 +}
 +
 +// ssaStmtList converts the statement n to SSA and adds it to s.
 +func (s *state) stmtList(l *NodeList) {
 +      for ; l != nil; l = l.Next {
 +              s.stmt(l.N)
 +      }
 +}
 +
 +// ssaStmt converts the statement n to SSA and adds it to s.
 +func (s *state) stmt(n *Node) {
 +      s.pushLine(n.Lineno)
 +      defer s.popLine()
 +
 +      // If s.curBlock is nil, then we're about to generate dead code.
 +      // We can't just short-circuit here, though,
 +      // because we check labels and gotos as part of SSA generation.
 +      // Provide a block for the dead code so that we don't have
 +      // to add special cases everywhere else.
 +      if s.curBlock == nil {
 +              dead := s.f.NewBlock(ssa.BlockPlain)
 +              s.startBlock(dead)
 +      }
 +
 +      s.stmtList(n.Ninit)
 +      switch n.Op {
 +
 +      case OBLOCK:
 +              s.stmtList(n.List)
 +
 +      // No-ops
 +      case OEMPTY, ODCLCONST, ODCLTYPE, OFALL:
 +
 +      // Expression statements
 +      case OCALLFUNC, OCALLMETH, OCALLINTER:
 +              s.call(n, callNormal)
 +      case ODEFER:
 +              s.call(n.Left, callDefer)
 +      case OPROC:
 +              s.call(n.Left, callGo)
 +
 +      case OAS2DOTTYPE:
 +              res, resok := s.dottype(n.Rlist.N, true)
 +              s.assign(n.List.N, res, false)
 +              s.assign(n.List.Next.N, resok, false)
 +              return
 +
 +      case ODCL:
 +              if n.Left.Class&PHEAP == 0 {
 +                      return
 +              }
 +              if compiling_runtime != 0 {
 +                      Fatalf("%v escapes to heap, not allowed in runtime.", n)
 +              }
 +
 +              // TODO: the old pass hides the details of PHEAP
 +              // variables behind ONAME nodes. Figure out if it's better
 +              // to rewrite the tree and make the heapaddr construct explicit
 +              // or to keep this detail hidden behind the scenes.
 +              palloc := prealloc[n.Left]
 +              if palloc == nil {
 +                      palloc = callnew(n.Left.Type)
 +                      prealloc[n.Left] = palloc
 +              }
 +              r := s.expr(palloc)
 +              s.assign(n.Left.Name.Heapaddr, r, false)
 +
 +      case OLABEL:
 +              sym := n.Left.Sym
 +
 +              if isblanksym(sym) {
 +                      // Empty identifier is valid but useless.
 +                      // See issues 11589, 11593.
 +                      return
 +              }
 +
 +              lab := s.label(sym)
 +
 +              // Associate label with its control flow node, if any
 +              if ctl := n.Name.Defn; ctl != nil {
 +                      switch ctl.Op {
 +                      case OFOR, OSWITCH, OSELECT:
 +                              s.labeledNodes[ctl] = lab
 +                      }
 +              }
 +
 +              if !lab.defined() {
 +                      lab.defNode = n
 +              } else {
 +                      s.Error("label %v already defined at %v", sym, Ctxt.Line(int(lab.defNode.Lineno)))
 +                      lab.reported = true
 +              }
 +              // The label might already have a target block via a goto.
 +              if lab.target == nil {
 +                      lab.target = s.f.NewBlock(ssa.BlockPlain)
 +              }
 +
 +              // go to that label (we pretend "label:" is preceded by "goto label")
 +              b := s.endBlock()
 +              b.AddEdgeTo(lab.target)
 +              s.startBlock(lab.target)
 +
 +      case OGOTO:
 +              sym := n.Left.Sym
 +
 +              lab := s.label(sym)
 +              if lab.target == nil {
 +                      lab.target = s.f.NewBlock(ssa.BlockPlain)
 +              }
 +              if !lab.used() {
 +                      lab.useNode = n
 +              }
 +
 +              if lab.defined() {
 +                      s.checkgoto(n, lab.defNode)
 +              } else {
 +                      s.fwdGotos = append(s.fwdGotos, n)
 +              }
 +
 +              b := s.endBlock()
 +              b.AddEdgeTo(lab.target)
 +
 +      case OAS, OASWB:
 +              // Check whether we can generate static data rather than code.
 +              // If so, ignore n and defer data generation until codegen.
 +              // Failure to do this causes writes to readonly symbols.
 +              if gen_as_init(n, true) {
 +                      var data []*Node
 +                      if s.f.StaticData != nil {
 +                              data = s.f.StaticData.([]*Node)
 +                      }
 +                      s.f.StaticData = append(data, n)
 +                      return
 +              }
 +              var r *ssa.Value
 +              if n.Right != nil {
 +                      if n.Right.Op == OSTRUCTLIT || n.Right.Op == OARRAYLIT {
 +                              // All literals with nonzero fields have already been
 +                              // rewritten during walk.  Any that remain are just T{}
 +                              // or equivalents.  Leave r = nil to get zeroing behavior.
 +                              if !iszero(n.Right) {
 +                                      Fatalf("literal with nonzero value in SSA: %v", n.Right)
 +                              }
 +                      } else {
 +                              r = s.expr(n.Right)
 +                      }
 +              }
 +              if n.Right != nil && n.Right.Op == OAPPEND {
 +                      // Yuck!  The frontend gets rid of the write barrier, but we need it!
 +                      // At least, we need it in the case where growslice is called.
 +                      // TODO: Do the write barrier on just the growslice branch.
 +                      // TODO: just add a ptr graying to the end of growslice?
 +                      // TODO: check whether we need to do this for ODOTTYPE and ORECV also.
 +                      // They get similar wb-removal treatment in walk.go:OAS.
 +                      s.assign(n.Left, r, true)
 +                      return
 +              }
 +              s.assign(n.Left, r, n.Op == OASWB)
 +
 +      case OIF:
 +              bThen := s.f.NewBlock(ssa.BlockPlain)
 +              bEnd := s.f.NewBlock(ssa.BlockPlain)
 +              var bElse *ssa.Block
 +              if n.Rlist != nil {
 +                      bElse = s.f.NewBlock(ssa.BlockPlain)
 +                      s.condBranch(n.Left, bThen, bElse, n.Likely)
 +              } else {
 +                      s.condBranch(n.Left, bThen, bEnd, n.Likely)
 +              }
 +
 +              s.startBlock(bThen)
 +              s.stmtList(n.Nbody)
 +              if b := s.endBlock(); b != nil {
 +                      b.AddEdgeTo(bEnd)
 +              }
 +
 +              if n.Rlist != nil {
 +                      s.startBlock(bElse)
 +                      s.stmtList(n.Rlist)
 +                      if b := s.endBlock(); b != nil {
 +                              b.AddEdgeTo(bEnd)
 +                      }
 +              }
 +              s.startBlock(bEnd)
 +
 +      case ORETURN:
 +              s.stmtList(n.List)
 +              s.stmtList(s.exitCode)
 +              m := s.mem()
 +              b := s.endBlock()
 +              b.Kind = ssa.BlockRet
 +              b.Control = m
 +      case ORETJMP:
 +              s.stmtList(n.List)
 +              s.stmtList(s.exitCode)
 +              m := s.mem()
 +              b := s.endBlock()
 +              b.Kind = ssa.BlockRetJmp
 +              b.Aux = n.Left.Sym
 +              b.Control = m
 +
 +      case OCONTINUE, OBREAK:
 +              var op string
 +              var to *ssa.Block
 +              switch n.Op {
 +              case OCONTINUE:
 +                      op = "continue"
 +                      to = s.continueTo
 +              case OBREAK:
 +                      op = "break"
 +                      to = s.breakTo
 +              }
 +              if n.Left == nil {
 +                      // plain break/continue
 +                      if to == nil {
 +                              s.Error("%s is not in a loop", op)
 +                              return
 +                      }
 +                      // nothing to do; "to" is already the correct target
 +              } else {
 +                      // labeled break/continue; look up the target
 +                      sym := n.Left.Sym
 +                      lab := s.label(sym)
 +                      if !lab.used() {
 +                              lab.useNode = n.Left
 +                      }
 +                      if !lab.defined() {
 +                              s.Error("%s label not defined: %v", op, sym)
 +                              lab.reported = true
 +                              return
 +                      }
 +                      switch n.Op {
 +                      case OCONTINUE:
 +                              to = lab.continueTarget
 +                      case OBREAK:
 +                              to = lab.breakTarget
 +                      }
 +                      if to == nil {
 +                              // Valid label but not usable with a break/continue here, e.g.:
 +                              // for {
 +                              //      continue abc
 +                              // }
 +                              // abc:
 +                              // for {}
 +                              s.Error("invalid %s label %v", op, sym)
 +                              lab.reported = true
 +                              return
 +                      }
 +              }
 +
 +              b := s.endBlock()
 +              b.AddEdgeTo(to)
 +
 +      case OFOR:
 +              // OFOR: for Ninit; Left; Right { Nbody }
 +              bCond := s.f.NewBlock(ssa.BlockPlain)
 +              bBody := s.f.NewBlock(ssa.BlockPlain)
 +              bIncr := s.f.NewBlock(ssa.BlockPlain)
 +              bEnd := s.f.NewBlock(ssa.BlockPlain)
 +
 +              // first, jump to condition test
 +              b := s.endBlock()
 +              b.AddEdgeTo(bCond)
 +
 +              // generate code to test condition
 +              s.startBlock(bCond)
 +              if n.Left != nil {
 +                      s.condBranch(n.Left, bBody, bEnd, 1)
 +              } else {
 +                      b := s.endBlock()
 +                      b.Kind = ssa.BlockPlain
 +                      b.AddEdgeTo(bBody)
 +              }
 +
 +              // set up for continue/break in body
 +              prevContinue := s.continueTo
 +              prevBreak := s.breakTo
 +              s.continueTo = bIncr
 +              s.breakTo = bEnd
 +              lab := s.labeledNodes[n]
 +              if lab != nil {
 +                      // labeled for loop
 +                      lab.continueTarget = bIncr
 +                      lab.breakTarget = bEnd
 +              }
 +
 +              // generate body
 +              s.startBlock(bBody)
 +              s.stmtList(n.Nbody)
 +
 +              // tear down continue/break
 +              s.continueTo = prevContinue
 +              s.breakTo = prevBreak
 +              if lab != nil {
 +                      lab.continueTarget = nil
 +                      lab.breakTarget = nil
 +              }
 +
 +              // done with body, goto incr
 +              if b := s.endBlock(); b != nil {
 +                      b.AddEdgeTo(bIncr)
 +              }
 +
 +              // generate incr
 +              s.startBlock(bIncr)
 +              if n.Right != nil {
 +                      s.stmt(n.Right)
 +              }
 +              if b := s.endBlock(); b != nil {
 +                      b.AddEdgeTo(bCond)
 +              }
 +              s.startBlock(bEnd)
 +
 +      case OSWITCH, OSELECT:
 +              // These have been mostly rewritten by the front end into their Nbody fields.
 +              // Our main task is to correctly hook up any break statements.
 +              bEnd := s.f.NewBlock(ssa.BlockPlain)
 +
 +              prevBreak := s.breakTo
 +              s.breakTo = bEnd
 +              lab := s.labeledNodes[n]
 +              if lab != nil {
 +                      // labeled
 +                      lab.breakTarget = bEnd
 +              }
 +
 +              // generate body code
 +              s.stmtList(n.Nbody)
 +
 +              s.breakTo = prevBreak
 +              if lab != nil {
 +                      lab.breakTarget = nil
 +              }
 +
 +              if b := s.endBlock(); b != nil {
 +                      b.AddEdgeTo(bEnd)
 +              }
 +              s.startBlock(bEnd)
 +
 +      case OVARKILL:
 +              // Insert a varkill op to record that a variable is no longer live.
 +              // We only care about liveness info at call sites, so putting the
 +              // varkill in the store chain is enough to keep it correctly ordered
 +              // with respect to call ops.
 +              if !canSSA(n.Left) {
 +                      s.vars[&memVar] = s.newValue1A(ssa.OpVarKill, ssa.TypeMem, n.Left, s.mem())
 +              }
 +
 +      case OCHECKNIL:
 +              p := s.expr(n.Left)
 +              s.nilCheck(p)
 +
 +      default:
 +              s.Unimplementedf("unhandled stmt %s", opnames[n.Op])
 +      }
 +}
 +
 +type opAndType struct {
- func (s *state) concreteEtype(t *Type) uint8 {
++      op    Op
++      etype EType
 +}
 +
 +var opToSSA = map[opAndType]ssa.Op{
 +      opAndType{OADD, TINT8}:    ssa.OpAdd8,
 +      opAndType{OADD, TUINT8}:   ssa.OpAdd8,
 +      opAndType{OADD, TINT16}:   ssa.OpAdd16,
 +      opAndType{OADD, TUINT16}:  ssa.OpAdd16,
 +      opAndType{OADD, TINT32}:   ssa.OpAdd32,
 +      opAndType{OADD, TUINT32}:  ssa.OpAdd32,
 +      opAndType{OADD, TPTR32}:   ssa.OpAdd32,
 +      opAndType{OADD, TINT64}:   ssa.OpAdd64,
 +      opAndType{OADD, TUINT64}:  ssa.OpAdd64,
 +      opAndType{OADD, TPTR64}:   ssa.OpAdd64,
 +      opAndType{OADD, TFLOAT32}: ssa.OpAdd32F,
 +      opAndType{OADD, TFLOAT64}: ssa.OpAdd64F,
 +
 +      opAndType{OSUB, TINT8}:    ssa.OpSub8,
 +      opAndType{OSUB, TUINT8}:   ssa.OpSub8,
 +      opAndType{OSUB, TINT16}:   ssa.OpSub16,
 +      opAndType{OSUB, TUINT16}:  ssa.OpSub16,
 +      opAndType{OSUB, TINT32}:   ssa.OpSub32,
 +      opAndType{OSUB, TUINT32}:  ssa.OpSub32,
 +      opAndType{OSUB, TINT64}:   ssa.OpSub64,
 +      opAndType{OSUB, TUINT64}:  ssa.OpSub64,
 +      opAndType{OSUB, TFLOAT32}: ssa.OpSub32F,
 +      opAndType{OSUB, TFLOAT64}: ssa.OpSub64F,
 +
 +      opAndType{ONOT, TBOOL}: ssa.OpNot,
 +
 +      opAndType{OMINUS, TINT8}:    ssa.OpNeg8,
 +      opAndType{OMINUS, TUINT8}:   ssa.OpNeg8,
 +      opAndType{OMINUS, TINT16}:   ssa.OpNeg16,
 +      opAndType{OMINUS, TUINT16}:  ssa.OpNeg16,
 +      opAndType{OMINUS, TINT32}:   ssa.OpNeg32,
 +      opAndType{OMINUS, TUINT32}:  ssa.OpNeg32,
 +      opAndType{OMINUS, TINT64}:   ssa.OpNeg64,
 +      opAndType{OMINUS, TUINT64}:  ssa.OpNeg64,
 +      opAndType{OMINUS, TFLOAT32}: ssa.OpNeg32F,
 +      opAndType{OMINUS, TFLOAT64}: ssa.OpNeg64F,
 +
 +      opAndType{OCOM, TINT8}:   ssa.OpCom8,
 +      opAndType{OCOM, TUINT8}:  ssa.OpCom8,
 +      opAndType{OCOM, TINT16}:  ssa.OpCom16,
 +      opAndType{OCOM, TUINT16}: ssa.OpCom16,
 +      opAndType{OCOM, TINT32}:  ssa.OpCom32,
 +      opAndType{OCOM, TUINT32}: ssa.OpCom32,
 +      opAndType{OCOM, TINT64}:  ssa.OpCom64,
 +      opAndType{OCOM, TUINT64}: ssa.OpCom64,
 +
 +      opAndType{OIMAG, TCOMPLEX64}:  ssa.OpComplexImag,
 +      opAndType{OIMAG, TCOMPLEX128}: ssa.OpComplexImag,
 +      opAndType{OREAL, TCOMPLEX64}:  ssa.OpComplexReal,
 +      opAndType{OREAL, TCOMPLEX128}: ssa.OpComplexReal,
 +
 +      opAndType{OMUL, TINT8}:    ssa.OpMul8,
 +      opAndType{OMUL, TUINT8}:   ssa.OpMul8,
 +      opAndType{OMUL, TINT16}:   ssa.OpMul16,
 +      opAndType{OMUL, TUINT16}:  ssa.OpMul16,
 +      opAndType{OMUL, TINT32}:   ssa.OpMul32,
 +      opAndType{OMUL, TUINT32}:  ssa.OpMul32,
 +      opAndType{OMUL, TINT64}:   ssa.OpMul64,
 +      opAndType{OMUL, TUINT64}:  ssa.OpMul64,
 +      opAndType{OMUL, TFLOAT32}: ssa.OpMul32F,
 +      opAndType{OMUL, TFLOAT64}: ssa.OpMul64F,
 +
 +      opAndType{ODIV, TFLOAT32}: ssa.OpDiv32F,
 +      opAndType{ODIV, TFLOAT64}: ssa.OpDiv64F,
 +
 +      opAndType{OHMUL, TINT8}:   ssa.OpHmul8,
 +      opAndType{OHMUL, TUINT8}:  ssa.OpHmul8u,
 +      opAndType{OHMUL, TINT16}:  ssa.OpHmul16,
 +      opAndType{OHMUL, TUINT16}: ssa.OpHmul16u,
 +      opAndType{OHMUL, TINT32}:  ssa.OpHmul32,
 +      opAndType{OHMUL, TUINT32}: ssa.OpHmul32u,
 +
 +      opAndType{ODIV, TINT8}:   ssa.OpDiv8,
 +      opAndType{ODIV, TUINT8}:  ssa.OpDiv8u,
 +      opAndType{ODIV, TINT16}:  ssa.OpDiv16,
 +      opAndType{ODIV, TUINT16}: ssa.OpDiv16u,
 +      opAndType{ODIV, TINT32}:  ssa.OpDiv32,
 +      opAndType{ODIV, TUINT32}: ssa.OpDiv32u,
 +      opAndType{ODIV, TINT64}:  ssa.OpDiv64,
 +      opAndType{ODIV, TUINT64}: ssa.OpDiv64u,
 +
 +      opAndType{OMOD, TINT8}:   ssa.OpMod8,
 +      opAndType{OMOD, TUINT8}:  ssa.OpMod8u,
 +      opAndType{OMOD, TINT16}:  ssa.OpMod16,
 +      opAndType{OMOD, TUINT16}: ssa.OpMod16u,
 +      opAndType{OMOD, TINT32}:  ssa.OpMod32,
 +      opAndType{OMOD, TUINT32}: ssa.OpMod32u,
 +      opAndType{OMOD, TINT64}:  ssa.OpMod64,
 +      opAndType{OMOD, TUINT64}: ssa.OpMod64u,
 +
 +      opAndType{OAND, TINT8}:   ssa.OpAnd8,
 +      opAndType{OAND, TUINT8}:  ssa.OpAnd8,
 +      opAndType{OAND, TINT16}:  ssa.OpAnd16,
 +      opAndType{OAND, TUINT16}: ssa.OpAnd16,
 +      opAndType{OAND, TINT32}:  ssa.OpAnd32,
 +      opAndType{OAND, TUINT32}: ssa.OpAnd32,
 +      opAndType{OAND, TINT64}:  ssa.OpAnd64,
 +      opAndType{OAND, TUINT64}: ssa.OpAnd64,
 +
 +      opAndType{OOR, TINT8}:   ssa.OpOr8,
 +      opAndType{OOR, TUINT8}:  ssa.OpOr8,
 +      opAndType{OOR, TINT16}:  ssa.OpOr16,
 +      opAndType{OOR, TUINT16}: ssa.OpOr16,
 +      opAndType{OOR, TINT32}:  ssa.OpOr32,
 +      opAndType{OOR, TUINT32}: ssa.OpOr32,
 +      opAndType{OOR, TINT64}:  ssa.OpOr64,
 +      opAndType{OOR, TUINT64}: ssa.OpOr64,
 +
 +      opAndType{OXOR, TINT8}:   ssa.OpXor8,
 +      opAndType{OXOR, TUINT8}:  ssa.OpXor8,
 +      opAndType{OXOR, TINT16}:  ssa.OpXor16,
 +      opAndType{OXOR, TUINT16}: ssa.OpXor16,
 +      opAndType{OXOR, TINT32}:  ssa.OpXor32,
 +      opAndType{OXOR, TUINT32}: ssa.OpXor32,
 +      opAndType{OXOR, TINT64}:  ssa.OpXor64,
 +      opAndType{OXOR, TUINT64}: ssa.OpXor64,
 +
 +      opAndType{OEQ, TBOOL}:      ssa.OpEq8,
 +      opAndType{OEQ, TINT8}:      ssa.OpEq8,
 +      opAndType{OEQ, TUINT8}:     ssa.OpEq8,
 +      opAndType{OEQ, TINT16}:     ssa.OpEq16,
 +      opAndType{OEQ, TUINT16}:    ssa.OpEq16,
 +      opAndType{OEQ, TINT32}:     ssa.OpEq32,
 +      opAndType{OEQ, TUINT32}:    ssa.OpEq32,
 +      opAndType{OEQ, TINT64}:     ssa.OpEq64,
 +      opAndType{OEQ, TUINT64}:    ssa.OpEq64,
 +      opAndType{OEQ, TINTER}:     ssa.OpEqInter,
 +      opAndType{OEQ, TARRAY}:     ssa.OpEqSlice,
 +      opAndType{OEQ, TFUNC}:      ssa.OpEqPtr,
 +      opAndType{OEQ, TMAP}:       ssa.OpEqPtr,
 +      opAndType{OEQ, TCHAN}:      ssa.OpEqPtr,
 +      opAndType{OEQ, TPTR64}:     ssa.OpEqPtr,
 +      opAndType{OEQ, TUINTPTR}:   ssa.OpEqPtr,
 +      opAndType{OEQ, TUNSAFEPTR}: ssa.OpEqPtr,
 +      opAndType{OEQ, TFLOAT64}:   ssa.OpEq64F,
 +      opAndType{OEQ, TFLOAT32}:   ssa.OpEq32F,
 +
 +      opAndType{ONE, TBOOL}:      ssa.OpNeq8,
 +      opAndType{ONE, TINT8}:      ssa.OpNeq8,
 +      opAndType{ONE, TUINT8}:     ssa.OpNeq8,
 +      opAndType{ONE, TINT16}:     ssa.OpNeq16,
 +      opAndType{ONE, TUINT16}:    ssa.OpNeq16,
 +      opAndType{ONE, TINT32}:     ssa.OpNeq32,
 +      opAndType{ONE, TUINT32}:    ssa.OpNeq32,
 +      opAndType{ONE, TINT64}:     ssa.OpNeq64,
 +      opAndType{ONE, TUINT64}:    ssa.OpNeq64,
 +      opAndType{ONE, TINTER}:     ssa.OpNeqInter,
 +      opAndType{ONE, TARRAY}:     ssa.OpNeqSlice,
 +      opAndType{ONE, TFUNC}:      ssa.OpNeqPtr,
 +      opAndType{ONE, TMAP}:       ssa.OpNeqPtr,
 +      opAndType{ONE, TCHAN}:      ssa.OpNeqPtr,
 +      opAndType{ONE, TPTR64}:     ssa.OpNeqPtr,
 +      opAndType{ONE, TUINTPTR}:   ssa.OpNeqPtr,
 +      opAndType{ONE, TUNSAFEPTR}: ssa.OpNeqPtr,
 +      opAndType{ONE, TFLOAT64}:   ssa.OpNeq64F,
 +      opAndType{ONE, TFLOAT32}:   ssa.OpNeq32F,
 +
 +      opAndType{OLT, TINT8}:    ssa.OpLess8,
 +      opAndType{OLT, TUINT8}:   ssa.OpLess8U,
 +      opAndType{OLT, TINT16}:   ssa.OpLess16,
 +      opAndType{OLT, TUINT16}:  ssa.OpLess16U,
 +      opAndType{OLT, TINT32}:   ssa.OpLess32,
 +      opAndType{OLT, TUINT32}:  ssa.OpLess32U,
 +      opAndType{OLT, TINT64}:   ssa.OpLess64,
 +      opAndType{OLT, TUINT64}:  ssa.OpLess64U,
 +      opAndType{OLT, TFLOAT64}: ssa.OpLess64F,
 +      opAndType{OLT, TFLOAT32}: ssa.OpLess32F,
 +
 +      opAndType{OGT, TINT8}:    ssa.OpGreater8,
 +      opAndType{OGT, TUINT8}:   ssa.OpGreater8U,
 +      opAndType{OGT, TINT16}:   ssa.OpGreater16,
 +      opAndType{OGT, TUINT16}:  ssa.OpGreater16U,
 +      opAndType{OGT, TINT32}:   ssa.OpGreater32,
 +      opAndType{OGT, TUINT32}:  ssa.OpGreater32U,
 +      opAndType{OGT, TINT64}:   ssa.OpGreater64,
 +      opAndType{OGT, TUINT64}:  ssa.OpGreater64U,
 +      opAndType{OGT, TFLOAT64}: ssa.OpGreater64F,
 +      opAndType{OGT, TFLOAT32}: ssa.OpGreater32F,
 +
 +      opAndType{OLE, TINT8}:    ssa.OpLeq8,
 +      opAndType{OLE, TUINT8}:   ssa.OpLeq8U,
 +      opAndType{OLE, TINT16}:   ssa.OpLeq16,
 +      opAndType{OLE, TUINT16}:  ssa.OpLeq16U,
 +      opAndType{OLE, TINT32}:   ssa.OpLeq32,
 +      opAndType{OLE, TUINT32}:  ssa.OpLeq32U,
 +      opAndType{OLE, TINT64}:   ssa.OpLeq64,
 +      opAndType{OLE, TUINT64}:  ssa.OpLeq64U,
 +      opAndType{OLE, TFLOAT64}: ssa.OpLeq64F,
 +      opAndType{OLE, TFLOAT32}: ssa.OpLeq32F,
 +
 +      opAndType{OGE, TINT8}:    ssa.OpGeq8,
 +      opAndType{OGE, TUINT8}:   ssa.OpGeq8U,
 +      opAndType{OGE, TINT16}:   ssa.OpGeq16,
 +      opAndType{OGE, TUINT16}:  ssa.OpGeq16U,
 +      opAndType{OGE, TINT32}:   ssa.OpGeq32,
 +      opAndType{OGE, TUINT32}:  ssa.OpGeq32U,
 +      opAndType{OGE, TINT64}:   ssa.OpGeq64,
 +      opAndType{OGE, TUINT64}:  ssa.OpGeq64U,
 +      opAndType{OGE, TFLOAT64}: ssa.OpGeq64F,
 +      opAndType{OGE, TFLOAT32}: ssa.OpGeq32F,
 +
 +      opAndType{OLROT, TUINT8}:  ssa.OpLrot8,
 +      opAndType{OLROT, TUINT16}: ssa.OpLrot16,
 +      opAndType{OLROT, TUINT32}: ssa.OpLrot32,
 +      opAndType{OLROT, TUINT64}: ssa.OpLrot64,
 +
 +      opAndType{OSQRT, TFLOAT64}: ssa.OpSqrt,
 +}
 +
- func (s *state) ssaOp(op uint8, t *Type) ssa.Op {
++func (s *state) concreteEtype(t *Type) EType {
 +      e := t.Etype
 +      switch e {
 +      default:
 +              return e
 +      case TINT:
 +              if s.config.IntSize == 8 {
 +                      return TINT64
 +              }
 +              return TINT32
 +      case TUINT:
 +              if s.config.IntSize == 8 {
 +                      return TUINT64
 +              }
 +              return TUINT32
 +      case TUINTPTR:
 +              if s.config.PtrSize == 8 {
 +                      return TUINT64
 +              }
 +              return TUINT32
 +      }
 +}
 +
-               s.Unimplementedf("unhandled binary op %s %s", opnames[op], Econv(int(etype), 0))
++func (s *state) ssaOp(op Op, t *Type) ssa.Op {
 +      etype := s.concreteEtype(t)
 +      x, ok := opToSSA[opAndType{op, etype}]
 +      if !ok {
-       op     uint8
-       etype1 uint8
-       etype2 uint8
++              s.Unimplementedf("unhandled binary op %s %s", opnames[op], Econv(etype))
 +      }
 +      return x
 +}
 +
 +func floatForComplex(t *Type) *Type {
 +      if t.Size() == 8 {
 +              return Types[TFLOAT32]
 +      } else {
 +              return Types[TFLOAT64]
 +      }
 +}
 +
 +type opAndTwoTypes struct {
-       etype1 uint8
-       etype2 uint8
++      op     Op
++      etype1 EType
++      etype2 EType
 +}
 +
 +type twoTypes struct {
-       intermediateType uint8
++      etype1 EType
++      etype2 EType
 +}
 +
 +type twoOpsAndType struct {
 +      op1              ssa.Op
 +      op2              ssa.Op
- func (s *state) ssaShiftOp(op uint8, t *Type, u *Type) ssa.Op {
++      intermediateType EType
 +}
 +
 +var fpConvOpToSSA = map[twoTypes]twoOpsAndType{
 +
 +      twoTypes{TINT8, TFLOAT32}:  twoOpsAndType{ssa.OpSignExt8to32, ssa.OpCvt32to32F, TINT32},
 +      twoTypes{TINT16, TFLOAT32}: twoOpsAndType{ssa.OpSignExt16to32, ssa.OpCvt32to32F, TINT32},
 +      twoTypes{TINT32, TFLOAT32}: twoOpsAndType{ssa.OpCopy, ssa.OpCvt32to32F, TINT32},
 +      twoTypes{TINT64, TFLOAT32}: twoOpsAndType{ssa.OpCopy, ssa.OpCvt64to32F, TINT64},
 +
 +      twoTypes{TINT8, TFLOAT64}:  twoOpsAndType{ssa.OpSignExt8to32, ssa.OpCvt32to64F, TINT32},
 +      twoTypes{TINT16, TFLOAT64}: twoOpsAndType{ssa.OpSignExt16to32, ssa.OpCvt32to64F, TINT32},
 +      twoTypes{TINT32, TFLOAT64}: twoOpsAndType{ssa.OpCopy, ssa.OpCvt32to64F, TINT32},
 +      twoTypes{TINT64, TFLOAT64}: twoOpsAndType{ssa.OpCopy, ssa.OpCvt64to64F, TINT64},
 +
 +      twoTypes{TFLOAT32, TINT8}:  twoOpsAndType{ssa.OpCvt32Fto32, ssa.OpTrunc32to8, TINT32},
 +      twoTypes{TFLOAT32, TINT16}: twoOpsAndType{ssa.OpCvt32Fto32, ssa.OpTrunc32to16, TINT32},
 +      twoTypes{TFLOAT32, TINT32}: twoOpsAndType{ssa.OpCvt32Fto32, ssa.OpCopy, TINT32},
 +      twoTypes{TFLOAT32, TINT64}: twoOpsAndType{ssa.OpCvt32Fto64, ssa.OpCopy, TINT64},
 +
 +      twoTypes{TFLOAT64, TINT8}:  twoOpsAndType{ssa.OpCvt64Fto32, ssa.OpTrunc32to8, TINT32},
 +      twoTypes{TFLOAT64, TINT16}: twoOpsAndType{ssa.OpCvt64Fto32, ssa.OpTrunc32to16, TINT32},
 +      twoTypes{TFLOAT64, TINT32}: twoOpsAndType{ssa.OpCvt64Fto32, ssa.OpCopy, TINT32},
 +      twoTypes{TFLOAT64, TINT64}: twoOpsAndType{ssa.OpCvt64Fto64, ssa.OpCopy, TINT64},
 +      // unsigned
 +      twoTypes{TUINT8, TFLOAT32}:  twoOpsAndType{ssa.OpZeroExt8to32, ssa.OpCvt32to32F, TINT32},
 +      twoTypes{TUINT16, TFLOAT32}: twoOpsAndType{ssa.OpZeroExt16to32, ssa.OpCvt32to32F, TINT32},
 +      twoTypes{TUINT32, TFLOAT32}: twoOpsAndType{ssa.OpZeroExt32to64, ssa.OpCvt64to32F, TINT64}, // go wide to dodge unsigned
 +      twoTypes{TUINT64, TFLOAT32}: twoOpsAndType{ssa.OpCopy, ssa.OpInvalid, TUINT64},            // Cvt64Uto32F, branchy code expansion instead
 +
 +      twoTypes{TUINT8, TFLOAT64}:  twoOpsAndType{ssa.OpZeroExt8to32, ssa.OpCvt32to64F, TINT32},
 +      twoTypes{TUINT16, TFLOAT64}: twoOpsAndType{ssa.OpZeroExt16to32, ssa.OpCvt32to64F, TINT32},
 +      twoTypes{TUINT32, TFLOAT64}: twoOpsAndType{ssa.OpZeroExt32to64, ssa.OpCvt64to64F, TINT64}, // go wide to dodge unsigned
 +      twoTypes{TUINT64, TFLOAT64}: twoOpsAndType{ssa.OpCopy, ssa.OpInvalid, TUINT64},            // Cvt64Uto64F, branchy code expansion instead
 +
 +      twoTypes{TFLOAT32, TUINT8}:  twoOpsAndType{ssa.OpCvt32Fto32, ssa.OpTrunc32to8, TINT32},
 +      twoTypes{TFLOAT32, TUINT16}: twoOpsAndType{ssa.OpCvt32Fto32, ssa.OpTrunc32to16, TINT32},
 +      twoTypes{TFLOAT32, TUINT32}: twoOpsAndType{ssa.OpCvt32Fto64, ssa.OpTrunc64to32, TINT64}, // go wide to dodge unsigned
 +      twoTypes{TFLOAT32, TUINT64}: twoOpsAndType{ssa.OpInvalid, ssa.OpCopy, TUINT64},          // Cvt32Fto64U, branchy code expansion instead
 +
 +      twoTypes{TFLOAT64, TUINT8}:  twoOpsAndType{ssa.OpCvt64Fto32, ssa.OpTrunc32to8, TINT32},
 +      twoTypes{TFLOAT64, TUINT16}: twoOpsAndType{ssa.OpCvt64Fto32, ssa.OpTrunc32to16, TINT32},
 +      twoTypes{TFLOAT64, TUINT32}: twoOpsAndType{ssa.OpCvt64Fto64, ssa.OpTrunc64to32, TINT64}, // go wide to dodge unsigned
 +      twoTypes{TFLOAT64, TUINT64}: twoOpsAndType{ssa.OpInvalid, ssa.OpCopy, TUINT64},          // Cvt64Fto64U, branchy code expansion instead
 +
 +      // float
 +      twoTypes{TFLOAT64, TFLOAT32}: twoOpsAndType{ssa.OpCvt64Fto32F, ssa.OpCopy, TFLOAT32},
 +      twoTypes{TFLOAT64, TFLOAT64}: twoOpsAndType{ssa.OpCopy, ssa.OpCopy, TFLOAT64},
 +      twoTypes{TFLOAT32, TFLOAT32}: twoOpsAndType{ssa.OpCopy, ssa.OpCopy, TFLOAT32},
 +      twoTypes{TFLOAT32, TFLOAT64}: twoOpsAndType{ssa.OpCvt32Fto64F, ssa.OpCopy, TFLOAT64},
 +}
 +
 +var shiftOpToSSA = map[opAndTwoTypes]ssa.Op{
 +      opAndTwoTypes{OLSH, TINT8, TUINT8}:   ssa.OpLsh8x8,
 +      opAndTwoTypes{OLSH, TUINT8, TUINT8}:  ssa.OpLsh8x8,
 +      opAndTwoTypes{OLSH, TINT8, TUINT16}:  ssa.OpLsh8x16,
 +      opAndTwoTypes{OLSH, TUINT8, TUINT16}: ssa.OpLsh8x16,
 +      opAndTwoTypes{OLSH, TINT8, TUINT32}:  ssa.OpLsh8x32,
 +      opAndTwoTypes{OLSH, TUINT8, TUINT32}: ssa.OpLsh8x32,
 +      opAndTwoTypes{OLSH, TINT8, TUINT64}:  ssa.OpLsh8x64,
 +      opAndTwoTypes{OLSH, TUINT8, TUINT64}: ssa.OpLsh8x64,
 +
 +      opAndTwoTypes{OLSH, TINT16, TUINT8}:   ssa.OpLsh16x8,
 +      opAndTwoTypes{OLSH, TUINT16, TUINT8}:  ssa.OpLsh16x8,
 +      opAndTwoTypes{OLSH, TINT16, TUINT16}:  ssa.OpLsh16x16,
 +      opAndTwoTypes{OLSH, TUINT16, TUINT16}: ssa.OpLsh16x16,
 +      opAndTwoTypes{OLSH, TINT16, TUINT32}:  ssa.OpLsh16x32,
 +      opAndTwoTypes{OLSH, TUINT16, TUINT32}: ssa.OpLsh16x32,
 +      opAndTwoTypes{OLSH, TINT16, TUINT64}:  ssa.OpLsh16x64,
 +      opAndTwoTypes{OLSH, TUINT16, TUINT64}: ssa.OpLsh16x64,
 +
 +      opAndTwoTypes{OLSH, TINT32, TUINT8}:   ssa.OpLsh32x8,
 +      opAndTwoTypes{OLSH, TUINT32, TUINT8}:  ssa.OpLsh32x8,
 +      opAndTwoTypes{OLSH, TINT32, TUINT16}:  ssa.OpLsh32x16,
 +      opAndTwoTypes{OLSH, TUINT32, TUINT16}: ssa.OpLsh32x16,
 +      opAndTwoTypes{OLSH, TINT32, TUINT32}:  ssa.OpLsh32x32,
 +      opAndTwoTypes{OLSH, TUINT32, TUINT32}: ssa.OpLsh32x32,
 +      opAndTwoTypes{OLSH, TINT32, TUINT64}:  ssa.OpLsh32x64,
 +      opAndTwoTypes{OLSH, TUINT32, TUINT64}: ssa.OpLsh32x64,
 +
 +      opAndTwoTypes{OLSH, TINT64, TUINT8}:   ssa.OpLsh64x8,
 +      opAndTwoTypes{OLSH, TUINT64, TUINT8}:  ssa.OpLsh64x8,
 +      opAndTwoTypes{OLSH, TINT64, TUINT16}:  ssa.OpLsh64x16,
 +      opAndTwoTypes{OLSH, TUINT64, TUINT16}: ssa.OpLsh64x16,
 +      opAndTwoTypes{OLSH, TINT64, TUINT32}:  ssa.OpLsh64x32,
 +      opAndTwoTypes{OLSH, TUINT64, TUINT32}: ssa.OpLsh64x32,
 +      opAndTwoTypes{OLSH, TINT64, TUINT64}:  ssa.OpLsh64x64,
 +      opAndTwoTypes{OLSH, TUINT64, TUINT64}: ssa.OpLsh64x64,
 +
 +      opAndTwoTypes{ORSH, TINT8, TUINT8}:   ssa.OpRsh8x8,
 +      opAndTwoTypes{ORSH, TUINT8, TUINT8}:  ssa.OpRsh8Ux8,
 +      opAndTwoTypes{ORSH, TINT8, TUINT16}:  ssa.OpRsh8x16,
 +      opAndTwoTypes{ORSH, TUINT8, TUINT16}: ssa.OpRsh8Ux16,
 +      opAndTwoTypes{ORSH, TINT8, TUINT32}:  ssa.OpRsh8x32,
 +      opAndTwoTypes{ORSH, TUINT8, TUINT32}: ssa.OpRsh8Ux32,
 +      opAndTwoTypes{ORSH, TINT8, TUINT64}:  ssa.OpRsh8x64,
 +      opAndTwoTypes{ORSH, TUINT8, TUINT64}: ssa.OpRsh8Ux64,
 +
 +      opAndTwoTypes{ORSH, TINT16, TUINT8}:   ssa.OpRsh16x8,
 +      opAndTwoTypes{ORSH, TUINT16, TUINT8}:  ssa.OpRsh16Ux8,
 +      opAndTwoTypes{ORSH, TINT16, TUINT16}:  ssa.OpRsh16x16,
 +      opAndTwoTypes{ORSH, TUINT16, TUINT16}: ssa.OpRsh16Ux16,
 +      opAndTwoTypes{ORSH, TINT16, TUINT32}:  ssa.OpRsh16x32,
 +      opAndTwoTypes{ORSH, TUINT16, TUINT32}: ssa.OpRsh16Ux32,
 +      opAndTwoTypes{ORSH, TINT16, TUINT64}:  ssa.OpRsh16x64,
 +      opAndTwoTypes{ORSH, TUINT16, TUINT64}: ssa.OpRsh16Ux64,
 +
 +      opAndTwoTypes{ORSH, TINT32, TUINT8}:   ssa.OpRsh32x8,
 +      opAndTwoTypes{ORSH, TUINT32, TUINT8}:  ssa.OpRsh32Ux8,
 +      opAndTwoTypes{ORSH, TINT32, TUINT16}:  ssa.OpRsh32x16,
 +      opAndTwoTypes{ORSH, TUINT32, TUINT16}: ssa.OpRsh32Ux16,
 +      opAndTwoTypes{ORSH, TINT32, TUINT32}:  ssa.OpRsh32x32,
 +      opAndTwoTypes{ORSH, TUINT32, TUINT32}: ssa.OpRsh32Ux32,
 +      opAndTwoTypes{ORSH, TINT32, TUINT64}:  ssa.OpRsh32x64,
 +      opAndTwoTypes{ORSH, TUINT32, TUINT64}: ssa.OpRsh32Ux64,
 +
 +      opAndTwoTypes{ORSH, TINT64, TUINT8}:   ssa.OpRsh64x8,
 +      opAndTwoTypes{ORSH, TUINT64, TUINT8}:  ssa.OpRsh64Ux8,
 +      opAndTwoTypes{ORSH, TINT64, TUINT16}:  ssa.OpRsh64x16,
 +      opAndTwoTypes{ORSH, TUINT64, TUINT16}: ssa.OpRsh64Ux16,
 +      opAndTwoTypes{ORSH, TINT64, TUINT32}:  ssa.OpRsh64x32,
 +      opAndTwoTypes{ORSH, TUINT64, TUINT32}: ssa.OpRsh64Ux32,
 +      opAndTwoTypes{ORSH, TINT64, TUINT64}:  ssa.OpRsh64x64,
 +      opAndTwoTypes{ORSH, TUINT64, TUINT64}: ssa.OpRsh64Ux64,
 +}
 +
-               s.Unimplementedf("unhandled shift op %s etype=%s/%s", opnames[op], Econv(int(etype1), 0), Econv(int(etype2), 0))
++func (s *state) ssaShiftOp(op Op, t *Type, u *Type) ssa.Op {
 +      etype1 := s.concreteEtype(t)
 +      etype2 := s.concreteEtype(u)
 +      x, ok := shiftOpToSSA[opAndTwoTypes{op, etype1, etype2}]
 +      if !ok {
- func (s *state) ssaRotateOp(op uint8, t *Type) ssa.Op {
++              s.Unimplementedf("unhandled shift op %s etype=%s/%s", opnames[op], Econv(etype1), Econv(etype2))
 +      }
 +      return x
 +}
 +
-               s.Unimplementedf("unhandled rotate op %s etype=%s", opnames[op], Econv(int(etype1), 0))
++func (s *state) ssaRotateOp(op Op, t *Type) ssa.Op {
 +      etype1 := s.concreteEtype(t)
 +      x, ok := opToSSA[opAndType{op, etype1}]
 +      if !ok {
-                       s.Fatalf("CONVNOP sign mismatch %v (%s) -> %v (%s)\n", from, Econv(int(from.Etype), 0), to, Econv(int(to.Etype), 0))
++              s.Unimplementedf("unhandled rotate op %s etype=%s", opnames[op], Econv(etype1))
 +      }
 +      return x
 +}
 +
 +// expr converts the expression n to ssa, adds it to s and returns the ssa result.
 +func (s *state) expr(n *Node) *ssa.Value {
 +      s.pushLine(n.Lineno)
 +      defer s.popLine()
 +
 +      s.stmtList(n.Ninit)
 +      switch n.Op {
 +      case OCFUNC:
 +              aux := s.lookupSymbol(n, &ssa.ExternSymbol{n.Type, n.Left.Sym})
 +              return s.entryNewValue1A(ssa.OpAddr, n.Type, aux, s.sb)
 +      case OPARAM:
 +              addr := s.addr(n, false)
 +              return s.newValue2(ssa.OpLoad, n.Left.Type, addr, s.mem())
 +      case ONAME:
 +              if n.Class == PFUNC {
 +                      // "value" of a function is the address of the function's closure
 +                      sym := funcsym(n.Sym)
 +                      aux := &ssa.ExternSymbol{n.Type, sym}
 +                      return s.entryNewValue1A(ssa.OpAddr, Ptrto(n.Type), aux, s.sb)
 +              }
 +              if canSSA(n) {
 +                      return s.variable(n, n.Type)
 +              }
 +              addr := s.addr(n, false)
 +              return s.newValue2(ssa.OpLoad, n.Type, addr, s.mem())
 +      case OCLOSUREVAR:
 +              addr := s.addr(n, false)
 +              return s.newValue2(ssa.OpLoad, n.Type, addr, s.mem())
 +      case OLITERAL:
 +              switch n.Val().Ctype() {
 +              case CTINT:
 +                      i := Mpgetfix(n.Val().U.(*Mpint))
 +                      switch n.Type.Size() {
 +                      case 1:
 +                              return s.constInt8(n.Type, int8(i))
 +                      case 2:
 +                              return s.constInt16(n.Type, int16(i))
 +                      case 4:
 +                              return s.constInt32(n.Type, int32(i))
 +                      case 8:
 +                              return s.constInt64(n.Type, i)
 +                      default:
 +                              s.Fatalf("bad integer size %d", n.Type.Size())
 +                              return nil
 +                      }
 +              case CTSTR:
 +                      return s.entryNewValue0A(ssa.OpConstString, n.Type, n.Val().U)
 +              case CTBOOL:
 +                      return s.constBool(n.Val().U.(bool))
 +              case CTNIL:
 +                      t := n.Type
 +                      switch {
 +                      case t.IsSlice():
 +                              return s.entryNewValue0(ssa.OpConstSlice, t)
 +                      case t.IsInterface():
 +                              return s.entryNewValue0(ssa.OpConstInterface, t)
 +                      default:
 +                              return s.entryNewValue0(ssa.OpConstNil, t)
 +                      }
 +              case CTFLT:
 +                      f := n.Val().U.(*Mpflt)
 +                      switch n.Type.Size() {
 +                      case 4:
 +                              // -0.0 literals need to be treated as if they were 0.0, adding 0.0 here
 +                              // accomplishes this while not affecting other values.
 +                              return s.constFloat32(n.Type, mpgetflt32(f)+0.0)
 +                      case 8:
 +                              return s.constFloat64(n.Type, mpgetflt(f)+0.0)
 +                      default:
 +                              s.Fatalf("bad float size %d", n.Type.Size())
 +                              return nil
 +                      }
 +              case CTCPLX:
 +                      c := n.Val().U.(*Mpcplx)
 +                      r := &c.Real
 +                      i := &c.Imag
 +                      switch n.Type.Size() {
 +                      case 8:
 +                              {
 +                                      pt := Types[TFLOAT32]
 +                                      // -0.0 literals need to be treated as if they were 0.0, adding 0.0 here
 +                                      // accomplishes this while not affecting other values.
 +                                      return s.newValue2(ssa.OpComplexMake, n.Type,
 +                                              s.constFloat32(pt, mpgetflt32(r)+0.0),
 +                                              s.constFloat32(pt, mpgetflt32(i)+0.0))
 +                              }
 +                      case 16:
 +                              {
 +                                      pt := Types[TFLOAT64]
 +                                      return s.newValue2(ssa.OpComplexMake, n.Type,
 +                                              s.constFloat64(pt, mpgetflt(r)+0.0),
 +                                              s.constFloat64(pt, mpgetflt(i)+0.0))
 +                              }
 +                      default:
 +                              s.Fatalf("bad float size %d", n.Type.Size())
 +                              return nil
 +                      }
 +
 +              default:
 +                      s.Unimplementedf("unhandled OLITERAL %v", n.Val().Ctype())
 +                      return nil
 +              }
 +      case OCONVNOP:
 +              to := n.Type
 +              from := n.Left.Type
 +
 +              // Assume everything will work out, so set up our return value.
 +              // Anything interesting that happens from here is a fatal.
 +              x := s.expr(n.Left)
 +
 +              // Special case for not confusing GC and liveness.
 +              // We don't want pointers accidentally classified
 +              // as not-pointers or vice-versa because of copy
 +              // elision.
 +              if to.IsPtr() != from.IsPtr() {
 +                      return s.newValue2(ssa.OpConvert, to, x, s.mem())
 +              }
 +
 +              v := s.newValue1(ssa.OpCopy, to, x) // ensure that v has the right type
 +
 +              // CONVNOP closure
 +              if to.Etype == TFUNC && from.IsPtr() {
 +                      return v
 +              }
 +
 +              // named <--> unnamed type or typed <--> untyped const
 +              if from.Etype == to.Etype {
 +                      return v
 +              }
 +
 +              // unsafe.Pointer <--> *T
 +              if to.Etype == TUNSAFEPTR && from.IsPtr() || from.Etype == TUNSAFEPTR && to.IsPtr() {
 +                      return v
 +              }
 +
 +              dowidth(from)
 +              dowidth(to)
 +              if from.Width != to.Width {
 +                      s.Fatalf("CONVNOP width mismatch %v (%d) -> %v (%d)\n", from, from.Width, to, to.Width)
 +                      return nil
 +              }
 +              if etypesign(from.Etype) != etypesign(to.Etype) {
-               s.Unimplementedf("unhandled OCONV %s -> %s", Econv(int(n.Left.Type.Etype), 0), Econv(int(n.Type.Etype), 0))
++                      s.Fatalf("CONVNOP sign mismatch %v (%s) -> %v (%s)\n", from, Econv(from.Etype), to, Econv(to.Etype))
 +                      return nil
 +              }
 +
 +              if flag_race != 0 {
 +                      // These appear to be fine, but they fail the
 +                      // integer constraint below, so okay them here.
 +                      // Sample non-integer conversion: map[string]string -> *uint8
 +                      return v
 +              }
 +
 +              if etypesign(from.Etype) == 0 {
 +                      s.Fatalf("CONVNOP unrecognized non-integer %v -> %v\n", from, to)
 +                      return nil
 +              }
 +
 +              // integer, same width, same sign
 +              return v
 +
 +      case OCONV:
 +              x := s.expr(n.Left)
 +              ft := n.Left.Type // from type
 +              tt := n.Type      // to type
 +              if ft.IsInteger() && tt.IsInteger() {
 +                      var op ssa.Op
 +                      if tt.Size() == ft.Size() {
 +                              op = ssa.OpCopy
 +                      } else if tt.Size() < ft.Size() {
 +                              // truncation
 +                              switch 10*ft.Size() + tt.Size() {
 +                              case 21:
 +                                      op = ssa.OpTrunc16to8
 +                              case 41:
 +                                      op = ssa.OpTrunc32to8
 +                              case 42:
 +                                      op = ssa.OpTrunc32to16
 +                              case 81:
 +                                      op = ssa.OpTrunc64to8
 +                              case 82:
 +                                      op = ssa.OpTrunc64to16
 +                              case 84:
 +                                      op = ssa.OpTrunc64to32
 +                              default:
 +                                      s.Fatalf("weird integer truncation %s -> %s", ft, tt)
 +                              }
 +                      } else if ft.IsSigned() {
 +                              // sign extension
 +                              switch 10*ft.Size() + tt.Size() {
 +                              case 12:
 +                                      op = ssa.OpSignExt8to16
 +                              case 14:
 +                                      op = ssa.OpSignExt8to32
 +                              case 18:
 +                                      op = ssa.OpSignExt8to64
 +                              case 24:
 +                                      op = ssa.OpSignExt16to32
 +                              case 28:
 +                                      op = ssa.OpSignExt16to64
 +                              case 48:
 +                                      op = ssa.OpSignExt32to64
 +                              default:
 +                                      s.Fatalf("bad integer sign extension %s -> %s", ft, tt)
 +                              }
 +                      } else {
 +                              // zero extension
 +                              switch 10*ft.Size() + tt.Size() {
 +                              case 12:
 +                                      op = ssa.OpZeroExt8to16
 +                              case 14:
 +                                      op = ssa.OpZeroExt8to32
 +                              case 18:
 +                                      op = ssa.OpZeroExt8to64
 +                              case 24:
 +                                      op = ssa.OpZeroExt16to32
 +                              case 28:
 +                                      op = ssa.OpZeroExt16to64
 +                              case 48:
 +                                      op = ssa.OpZeroExt32to64
 +                              default:
 +                                      s.Fatalf("weird integer sign extension %s -> %s", ft, tt)
 +                              }
 +                      }
 +                      return s.newValue1(op, n.Type, x)
 +              }
 +
 +              if ft.IsFloat() || tt.IsFloat() {
 +                      conv, ok := fpConvOpToSSA[twoTypes{s.concreteEtype(ft), s.concreteEtype(tt)}]
 +                      if !ok {
 +                              s.Fatalf("weird float conversion %s -> %s", ft, tt)
 +                      }
 +                      op1, op2, it := conv.op1, conv.op2, conv.intermediateType
 +
 +                      if op1 != ssa.OpInvalid && op2 != ssa.OpInvalid {
 +                              // normal case, not tripping over unsigned 64
 +                              if op1 == ssa.OpCopy {
 +                                      if op2 == ssa.OpCopy {
 +                                              return x
 +                                      }
 +                                      return s.newValue1(op2, n.Type, x)
 +                              }
 +                              if op2 == ssa.OpCopy {
 +                                      return s.newValue1(op1, n.Type, x)
 +                              }
 +                              return s.newValue1(op2, n.Type, s.newValue1(op1, Types[it], x))
 +                      }
 +                      // Tricky 64-bit unsigned cases.
 +                      if ft.IsInteger() {
 +                              // therefore tt is float32 or float64, and ft is also unsigned
 +                              if tt.Size() == 4 {
 +                                      return s.uint64Tofloat32(n, x, ft, tt)
 +                              }
 +                              if tt.Size() == 8 {
 +                                      return s.uint64Tofloat64(n, x, ft, tt)
 +                              }
 +                              s.Fatalf("weird unsigned integer to float conversion %s -> %s", ft, tt)
 +                      }
 +                      // therefore ft is float32 or float64, and tt is unsigned integer
 +                      if ft.Size() == 4 {
 +                              return s.float32ToUint64(n, x, ft, tt)
 +                      }
 +                      if ft.Size() == 8 {
 +                              return s.float64ToUint64(n, x, ft, tt)
 +                      }
 +                      s.Fatalf("weird float to unsigned integer conversion %s -> %s", ft, tt)
 +                      return nil
 +              }
 +
 +              if ft.IsComplex() && tt.IsComplex() {
 +                      var op ssa.Op
 +                      if ft.Size() == tt.Size() {
 +                              op = ssa.OpCopy
 +                      } else if ft.Size() == 8 && tt.Size() == 16 {
 +                              op = ssa.OpCvt32Fto64F
 +                      } else if ft.Size() == 16 && tt.Size() == 8 {
 +                              op = ssa.OpCvt64Fto32F
 +                      } else {
 +                              s.Fatalf("weird complex conversion %s -> %s", ft, tt)
 +                      }
 +                      ftp := floatForComplex(ft)
 +                      ttp := floatForComplex(tt)
 +                      return s.newValue2(ssa.OpComplexMake, tt,
 +                              s.newValue1(op, ttp, s.newValue1(ssa.OpComplexReal, ftp, x)),
 +                              s.newValue1(op, ttp, s.newValue1(ssa.OpComplexImag, ftp, x)))
 +              }
 +
-                               // TODO: maybe just one writeBarrierEnabled check?
++              s.Unimplementedf("unhandled OCONV %s -> %s", Econv(n.Left.Type.Etype), Econv(n.Type.Etype))
 +              return nil
 +
 +      case ODOTTYPE:
 +              res, _ := s.dottype(n, false)
 +              return res
 +
 +      // binary ops
 +      case OLT, OEQ, ONE, OLE, OGE, OGT:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              if n.Left.Type.IsComplex() {
 +                      pt := floatForComplex(n.Left.Type)
 +                      op := s.ssaOp(OEQ, pt)
 +                      r := s.newValue2(op, Types[TBOOL], s.newValue1(ssa.OpComplexReal, pt, a), s.newValue1(ssa.OpComplexReal, pt, b))
 +                      i := s.newValue2(op, Types[TBOOL], s.newValue1(ssa.OpComplexImag, pt, a), s.newValue1(ssa.OpComplexImag, pt, b))
 +                      c := s.newValue2(ssa.OpAnd8, Types[TBOOL], r, i)
 +                      switch n.Op {
 +                      case OEQ:
 +                              return c
 +                      case ONE:
 +                              return s.newValue1(ssa.OpNot, Types[TBOOL], c)
 +                      default:
 +                              s.Fatalf("ordered complex compare %s", opnames[n.Op])
 +                      }
 +              }
 +              return s.newValue2(s.ssaOp(n.Op, n.Left.Type), Types[TBOOL], a, b)
 +      case OMUL:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              if n.Type.IsComplex() {
 +                      mulop := ssa.OpMul64F
 +                      addop := ssa.OpAdd64F
 +                      subop := ssa.OpSub64F
 +                      pt := floatForComplex(n.Type) // Could be Float32 or Float64
 +                      wt := Types[TFLOAT64]         // Compute in Float64 to minimize cancellation error
 +
 +                      areal := s.newValue1(ssa.OpComplexReal, pt, a)
 +                      breal := s.newValue1(ssa.OpComplexReal, pt, b)
 +                      aimag := s.newValue1(ssa.OpComplexImag, pt, a)
 +                      bimag := s.newValue1(ssa.OpComplexImag, pt, b)
 +
 +                      if pt != wt { // Widen for calculation
 +                              areal = s.newValue1(ssa.OpCvt32Fto64F, wt, areal)
 +                              breal = s.newValue1(ssa.OpCvt32Fto64F, wt, breal)
 +                              aimag = s.newValue1(ssa.OpCvt32Fto64F, wt, aimag)
 +                              bimag = s.newValue1(ssa.OpCvt32Fto64F, wt, bimag)
 +                      }
 +
 +                      xreal := s.newValue2(subop, wt, s.newValue2(mulop, wt, areal, breal), s.newValue2(mulop, wt, aimag, bimag))
 +                      ximag := s.newValue2(addop, wt, s.newValue2(mulop, wt, areal, bimag), s.newValue2(mulop, wt, aimag, breal))
 +
 +                      if pt != wt { // Narrow to store back
 +                              xreal = s.newValue1(ssa.OpCvt64Fto32F, pt, xreal)
 +                              ximag = s.newValue1(ssa.OpCvt64Fto32F, pt, ximag)
 +                      }
 +
 +                      return s.newValue2(ssa.OpComplexMake, n.Type, xreal, ximag)
 +              }
 +              return s.newValue2(s.ssaOp(n.Op, n.Type), a.Type, a, b)
 +
 +      case ODIV:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              if n.Type.IsComplex() {
 +                      // TODO this is not executed because the front-end substitutes a runtime call.
 +                      // That probably ought to change; with modest optimization the widen/narrow
 +                      // conversions could all be elided in larger expression trees.
 +                      mulop := ssa.OpMul64F
 +                      addop := ssa.OpAdd64F
 +                      subop := ssa.OpSub64F
 +                      divop := ssa.OpDiv64F
 +                      pt := floatForComplex(n.Type) // Could be Float32 or Float64
 +                      wt := Types[TFLOAT64]         // Compute in Float64 to minimize cancellation error
 +
 +                      areal := s.newValue1(ssa.OpComplexReal, pt, a)
 +                      breal := s.newValue1(ssa.OpComplexReal, pt, b)
 +                      aimag := s.newValue1(ssa.OpComplexImag, pt, a)
 +                      bimag := s.newValue1(ssa.OpComplexImag, pt, b)
 +
 +                      if pt != wt { // Widen for calculation
 +                              areal = s.newValue1(ssa.OpCvt32Fto64F, wt, areal)
 +                              breal = s.newValue1(ssa.OpCvt32Fto64F, wt, breal)
 +                              aimag = s.newValue1(ssa.OpCvt32Fto64F, wt, aimag)
 +                              bimag = s.newValue1(ssa.OpCvt32Fto64F, wt, bimag)
 +                      }
 +
 +                      denom := s.newValue2(addop, wt, s.newValue2(mulop, wt, breal, breal), s.newValue2(mulop, wt, bimag, bimag))
 +                      xreal := s.newValue2(addop, wt, s.newValue2(mulop, wt, areal, breal), s.newValue2(mulop, wt, aimag, bimag))
 +                      ximag := s.newValue2(subop, wt, s.newValue2(mulop, wt, aimag, breal), s.newValue2(mulop, wt, areal, bimag))
 +
 +                      // TODO not sure if this is best done in wide precision or narrow
 +                      // Double-rounding might be an issue.
 +                      // Note that the pre-SSA implementation does the entire calculation
 +                      // in wide format, so wide is compatible.
 +                      xreal = s.newValue2(divop, wt, xreal, denom)
 +                      ximag = s.newValue2(divop, wt, ximag, denom)
 +
 +                      if pt != wt { // Narrow to store back
 +                              xreal = s.newValue1(ssa.OpCvt64Fto32F, pt, xreal)
 +                              ximag = s.newValue1(ssa.OpCvt64Fto32F, pt, ximag)
 +                      }
 +                      return s.newValue2(ssa.OpComplexMake, n.Type, xreal, ximag)
 +              }
 +              if n.Type.IsFloat() {
 +                      return s.newValue2(s.ssaOp(n.Op, n.Type), a.Type, a, b)
 +              } else {
 +                      // do a size-appropriate check for zero
 +                      cmp := s.newValue2(s.ssaOp(ONE, n.Type), Types[TBOOL], b, s.zeroVal(n.Type))
 +                      s.check(cmp, panicdivide)
 +                      return s.newValue2(s.ssaOp(n.Op, n.Type), a.Type, a, b)
 +              }
 +      case OMOD:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              // do a size-appropriate check for zero
 +              cmp := s.newValue2(s.ssaOp(ONE, n.Type), Types[TBOOL], b, s.zeroVal(n.Type))
 +              s.check(cmp, panicdivide)
 +              return s.newValue2(s.ssaOp(n.Op, n.Type), a.Type, a, b)
 +      case OADD, OSUB:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              if n.Type.IsComplex() {
 +                      pt := floatForComplex(n.Type)
 +                      op := s.ssaOp(n.Op, pt)
 +                      return s.newValue2(ssa.OpComplexMake, n.Type,
 +                              s.newValue2(op, pt, s.newValue1(ssa.OpComplexReal, pt, a), s.newValue1(ssa.OpComplexReal, pt, b)),
 +                              s.newValue2(op, pt, s.newValue1(ssa.OpComplexImag, pt, a), s.newValue1(ssa.OpComplexImag, pt, b)))
 +              }
 +              return s.newValue2(s.ssaOp(n.Op, n.Type), a.Type, a, b)
 +      case OAND, OOR, OHMUL, OXOR:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              return s.newValue2(s.ssaOp(n.Op, n.Type), a.Type, a, b)
 +      case OLSH, ORSH:
 +              a := s.expr(n.Left)
 +              b := s.expr(n.Right)
 +              return s.newValue2(s.ssaShiftOp(n.Op, n.Type, n.Right.Type), a.Type, a, b)
 +      case OLROT:
 +              a := s.expr(n.Left)
 +              i := n.Right.Int()
 +              if i <= 0 || i >= n.Type.Size()*8 {
 +                      s.Fatalf("Wrong rotate distance for LROT, expected 1 through %d, saw %d", n.Type.Size()*8-1, i)
 +              }
 +              return s.newValue1I(s.ssaRotateOp(n.Op, n.Type), a.Type, i, a)
 +      case OANDAND, OOROR:
 +              // To implement OANDAND (and OOROR), we introduce a
 +              // new temporary variable to hold the result. The
 +              // variable is associated with the OANDAND node in the
 +              // s.vars table (normally variables are only
 +              // associated with ONAME nodes). We convert
 +              //     A && B
 +              // to
 +              //     var = A
 +              //     if var {
 +              //         var = B
 +              //     }
 +              // Using var in the subsequent block introduces the
 +              // necessary phi variable.
 +              el := s.expr(n.Left)
 +              s.vars[n] = el
 +
 +              b := s.endBlock()
 +              b.Kind = ssa.BlockIf
 +              b.Control = el
 +              // In theory, we should set b.Likely here based on context.
 +              // However, gc only gives us likeliness hints
 +              // in a single place, for plain OIF statements,
 +              // and passing around context is finnicky, so don't bother for now.
 +
 +              bRight := s.f.NewBlock(ssa.BlockPlain)
 +              bResult := s.f.NewBlock(ssa.BlockPlain)
 +              if n.Op == OANDAND {
 +                      b.AddEdgeTo(bRight)
 +                      b.AddEdgeTo(bResult)
 +              } else if n.Op == OOROR {
 +                      b.AddEdgeTo(bResult)
 +                      b.AddEdgeTo(bRight)
 +              }
 +
 +              s.startBlock(bRight)
 +              er := s.expr(n.Right)
 +              s.vars[n] = er
 +
 +              b = s.endBlock()
 +              b.AddEdgeTo(bResult)
 +
 +              s.startBlock(bResult)
 +              return s.variable(n, Types[TBOOL])
 +      case OCOMPLEX:
 +              r := s.expr(n.Left)
 +              i := s.expr(n.Right)
 +              return s.newValue2(ssa.OpComplexMake, n.Type, r, i)
 +
 +      // unary ops
 +      case OMINUS:
 +              a := s.expr(n.Left)
 +              if n.Type.IsComplex() {
 +                      tp := floatForComplex(n.Type)
 +                      negop := s.ssaOp(n.Op, tp)
 +                      return s.newValue2(ssa.OpComplexMake, n.Type,
 +                              s.newValue1(negop, tp, s.newValue1(ssa.OpComplexReal, tp, a)),
 +                              s.newValue1(negop, tp, s.newValue1(ssa.OpComplexImag, tp, a)))
 +              }
 +              return s.newValue1(s.ssaOp(n.Op, n.Type), a.Type, a)
 +      case ONOT, OCOM, OSQRT:
 +              a := s.expr(n.Left)
 +              return s.newValue1(s.ssaOp(n.Op, n.Type), a.Type, a)
 +      case OIMAG, OREAL:
 +              a := s.expr(n.Left)
 +              return s.newValue1(s.ssaOp(n.Op, n.Left.Type), n.Type, a)
 +      case OPLUS:
 +              return s.expr(n.Left)
 +
 +      case OADDR:
 +              return s.addr(n.Left, n.Bounded)
 +
 +      case OINDREG:
 +              if int(n.Reg) != Thearch.REGSP {
 +                      s.Unimplementedf("OINDREG of non-SP register %s in expr: %v", obj.Rconv(int(n.Reg)), n)
 +                      return nil
 +              }
 +              addr := s.entryNewValue1I(ssa.OpOffPtr, Ptrto(n.Type), n.Xoffset, s.sp)
 +              return s.newValue2(ssa.OpLoad, n.Type, addr, s.mem())
 +
 +      case OIND:
 +              p := s.expr(n.Left)
 +              s.nilCheck(p)
 +              return s.newValue2(ssa.OpLoad, n.Type, p, s.mem())
 +
 +      case ODOT:
 +              // TODO: fix when we can SSA struct types.
 +              p := s.addr(n, false)
 +              return s.newValue2(ssa.OpLoad, n.Type, p, s.mem())
 +
 +      case ODOTPTR:
 +              p := s.expr(n.Left)
 +              s.nilCheck(p)
 +              p = s.newValue2(ssa.OpAddPtr, p.Type, p, s.constInt(Types[TINT], n.Xoffset))
 +              return s.newValue2(ssa.OpLoad, n.Type, p, s.mem())
 +
 +      case OINDEX:
 +              switch {
 +              case n.Left.Type.IsString():
 +                      a := s.expr(n.Left)
 +                      i := s.expr(n.Right)
 +                      i = s.extendIndex(i)
 +                      if !n.Bounded {
 +                              len := s.newValue1(ssa.OpStringLen, Types[TINT], a)
 +                              s.boundsCheck(i, len)
 +                      }
 +                      ptrtyp := Ptrto(Types[TUINT8])
 +                      ptr := s.newValue1(ssa.OpStringPtr, ptrtyp, a)
 +                      ptr = s.newValue2(ssa.OpAddPtr, ptrtyp, ptr, i)
 +                      return s.newValue2(ssa.OpLoad, Types[TUINT8], ptr, s.mem())
 +              case n.Left.Type.IsSlice():
 +                      p := s.addr(n, false)
 +                      return s.newValue2(ssa.OpLoad, n.Left.Type.Type, p, s.mem())
 +              case n.Left.Type.IsArray():
 +                      // TODO: fix when we can SSA arrays of length 1.
 +                      p := s.addr(n, false)
 +                      return s.newValue2(ssa.OpLoad, n.Left.Type.Type, p, s.mem())
 +              default:
 +                      s.Fatalf("bad type for index %v", n.Left.Type)
 +                      return nil
 +              }
 +
 +      case OLEN, OCAP:
 +              switch {
 +              case n.Left.Type.IsSlice():
 +                      op := ssa.OpSliceLen
 +                      if n.Op == OCAP {
 +                              op = ssa.OpSliceCap
 +                      }
 +                      return s.newValue1(op, Types[TINT], s.expr(n.Left))
 +              case n.Left.Type.IsString(): // string; not reachable for OCAP
 +                      return s.newValue1(ssa.OpStringLen, Types[TINT], s.expr(n.Left))
 +              case n.Left.Type.IsMap(), n.Left.Type.IsChan():
 +                      return s.referenceTypeBuiltin(n, s.expr(n.Left))
 +              default: // array
 +                      return s.constInt(Types[TINT], n.Left.Type.Bound)
 +              }
 +
 +      case OSPTR:
 +              a := s.expr(n.Left)
 +              if n.Left.Type.IsSlice() {
 +                      return s.newValue1(ssa.OpSlicePtr, n.Type, a)
 +              } else {
 +                      return s.newValue1(ssa.OpStringPtr, n.Type, a)
 +              }
 +
 +      case OITAB:
 +              a := s.expr(n.Left)
 +              return s.newValue1(ssa.OpITab, n.Type, a)
 +
 +      case OEFACE:
 +              tab := s.expr(n.Left)
 +              data := s.expr(n.Right)
 +              // The frontend allows putting things like struct{*byte} in
 +              // the data portion of an eface.  But we don't want struct{*byte}
 +              // as a register type because (among other reasons) the liveness
 +              // analysis is confused by the "fat" variables that result from
 +              // such types being spilled.
 +              // So here we ensure that we are selecting the underlying pointer
 +              // when we build an eface.
 +              for !data.Type.IsPtr() {
 +                      switch {
 +                      case data.Type.IsArray():
 +                              data = s.newValue2(ssa.OpArrayIndex, data.Type.Elem(), data, s.constInt(Types[TINT], 0))
 +                      case data.Type.IsStruct():
 +                              for i := data.Type.NumFields() - 1; i >= 0; i-- {
 +                                      f := data.Type.FieldType(i)
 +                                      if f.Size() == 0 {
 +                                              // eface type could also be struct{p *byte; q [0]int}
 +                                              continue
 +                                      }
 +                                      data = s.newValue1I(ssa.OpStructSelect, f, data.Type.FieldOff(i), data)
 +                                      break
 +                              }
 +                      default:
 +                              s.Fatalf("type being put into an eface isn't a pointer")
 +                      }
 +              }
 +              return s.newValue2(ssa.OpIMake, n.Type, tab, data)
 +
 +      case OSLICE, OSLICEARR:
 +              v := s.expr(n.Left)
 +              var i, j *ssa.Value
 +              if n.Right.Left != nil {
 +                      i = s.extendIndex(s.expr(n.Right.Left))
 +              }
 +              if n.Right.Right != nil {
 +                      j = s.extendIndex(s.expr(n.Right.Right))
 +              }
 +              p, l, c := s.slice(n.Left.Type, v, i, j, nil)
 +              return s.newValue3(ssa.OpSliceMake, n.Type, p, l, c)
 +      case OSLICESTR:
 +              v := s.expr(n.Left)
 +              var i, j *ssa.Value
 +              if n.Right.Left != nil {
 +                      i = s.extendIndex(s.expr(n.Right.Left))
 +              }
 +              if n.Right.Right != nil {
 +                      j = s.extendIndex(s.expr(n.Right.Right))
 +              }
 +              p, l, _ := s.slice(n.Left.Type, v, i, j, nil)
 +              return s.newValue2(ssa.OpStringMake, n.Type, p, l)
 +      case OSLICE3, OSLICE3ARR:
 +              v := s.expr(n.Left)
 +              var i *ssa.Value
 +              if n.Right.Left != nil {
 +                      i = s.extendIndex(s.expr(n.Right.Left))
 +              }
 +              j := s.extendIndex(s.expr(n.Right.Right.Left))
 +              k := s.extendIndex(s.expr(n.Right.Right.Right))
 +              p, l, c := s.slice(n.Left.Type, v, i, j, k)
 +              return s.newValue3(ssa.OpSliceMake, n.Type, p, l, c)
 +
 +      case OCALLFUNC, OCALLINTER, OCALLMETH:
 +              return s.call(n, callNormal)
 +
 +      case OGETG:
 +              return s.newValue1(ssa.OpGetG, n.Type, s.mem())
 +
 +      case OAPPEND:
 +              // append(s, e1, e2, e3).  Compile like:
 +              // ptr,len,cap := s
 +              // newlen := len + 3
 +              // if newlen > s.cap {
 +              //     ptr,_,cap = growslice(s, newlen)
 +              // }
 +              // *(ptr+len) = e1
 +              // *(ptr+len+1) = e2
 +              // *(ptr+len+2) = e3
 +              // makeslice(ptr,newlen,cap)
 +
 +              et := n.Type.Type
 +              pt := Ptrto(et)
 +
 +              // Evaluate slice
 +              slice := s.expr(n.List.N)
 +
 +              // Allocate new blocks
 +              grow := s.f.NewBlock(ssa.BlockPlain)
 +              assign := s.f.NewBlock(ssa.BlockPlain)
 +
 +              // Decide if we need to grow
 +              nargs := int64(count(n.List) - 1)
 +              p := s.newValue1(ssa.OpSlicePtr, pt, slice)
 +              l := s.newValue1(ssa.OpSliceLen, Types[TINT], slice)
 +              c := s.newValue1(ssa.OpSliceCap, Types[TINT], slice)
 +              nl := s.newValue2(s.ssaOp(OADD, Types[TINT]), Types[TINT], l, s.constInt(Types[TINT], nargs))
 +              cmp := s.newValue2(s.ssaOp(OGT, Types[TINT]), Types[TBOOL], nl, c)
 +              s.vars[&ptrVar] = p
 +              s.vars[&capVar] = c
 +              b := s.endBlock()
 +              b.Kind = ssa.BlockIf
 +              b.Likely = ssa.BranchUnlikely
 +              b.Control = cmp
 +              b.AddEdgeTo(grow)
 +              b.AddEdgeTo(assign)
 +
 +              // Call growslice
 +              s.startBlock(grow)
 +              taddr := s.newValue1A(ssa.OpAddr, Types[TUINTPTR], &ssa.ExternSymbol{Types[TUINTPTR], typenamesym(n.Type)}, s.sb)
 +
 +              r := s.rtcall(growslice, true, []*Type{pt, Types[TINT], Types[TINT]}, taddr, p, l, c, nl)
 +
 +              s.vars[&ptrVar] = r[0]
 +              // Note: we don't need to read r[1], the result's length.  It will be nl.
 +              // (or maybe we should, we just have to spill/restore nl otherwise?)
 +              s.vars[&capVar] = r[2]
 +              b = s.endBlock()
 +              b.AddEdgeTo(assign)
 +
 +              // assign new elements to slots
 +              s.startBlock(assign)
 +
 +              // Evaluate args
 +              args := make([]*ssa.Value, 0, nargs)
 +              store := make([]bool, 0, nargs)
 +              for l := n.List.Next; l != nil; l = l.Next {
 +                      if canSSAType(l.N.Type) {
 +                              args = append(args, s.expr(l.N))
 +                              store = append(store, true)
 +                      } else {
 +                              args = append(args, s.addr(l.N, false))
 +                              store = append(store, false)
 +                      }
 +              }
 +
 +              p = s.variable(&ptrVar, pt)          // generates phi for ptr
 +              c = s.variable(&capVar, Types[TINT]) // generates phi for cap
 +              p2 := s.newValue2(ssa.OpPtrIndex, pt, p, l)
 +              for i, arg := range args {
 +                      addr := s.newValue2(ssa.OpPtrIndex, pt, p2, s.constInt(Types[TINT], int64(i)))
 +                      if store[i] {
 +                              s.vars[&memVar] = s.newValue3I(ssa.OpStore, ssa.TypeMem, et.Size(), addr, arg, s.mem())
 +                      } else {
 +                              s.vars[&memVar] = s.newValue3I(ssa.OpMove, ssa.TypeMem, et.Size(), addr, arg, s.mem())
 +                      }
 +                      if haspointers(et) {
 +                              // TODO: just one write barrier call for all of these writes?
- func etypesign(e uint8) int8 {
++                              // TODO: maybe just one writeBarrier.enabled check?
 +                              s.insertWB(et, addr, n.Lineno)
 +                      }
 +              }
 +
 +              // make result
 +              delete(s.vars, &ptrVar)
 +              delete(s.vars, &capVar)
 +              return s.newValue3(ssa.OpSliceMake, n.Type, p, nl, c)
 +
 +      default:
 +              s.Unimplementedf("unhandled expr %s", opnames[n.Op])
 +              return nil
 +      }
 +}
 +
 +// condBranch evaluates the boolean expression cond and branches to yes
 +// if cond is true and no if cond is false.
 +// This function is intended to handle && and || better than just calling
 +// s.expr(cond) and branching on the result.
 +func (s *state) condBranch(cond *Node, yes, no *ssa.Block, likely int8) {
 +      if cond.Op == OANDAND {
 +              mid := s.f.NewBlock(ssa.BlockPlain)
 +              s.stmtList(cond.Ninit)
 +              s.condBranch(cond.Left, mid, no, max8(likely, 0))
 +              s.startBlock(mid)
 +              s.condBranch(cond.Right, yes, no, likely)
 +              return
 +              // Note: if likely==1, then both recursive calls pass 1.
 +              // If likely==-1, then we don't have enough information to decide
 +              // whether the first branch is likely or not.  So we pass 0 for
 +              // the likeliness of the first branch.
 +              // TODO: have the frontend give us branch prediction hints for
 +              // OANDAND and OOROR nodes (if it ever has such info).
 +      }
 +      if cond.Op == OOROR {
 +              mid := s.f.NewBlock(ssa.BlockPlain)
 +              s.stmtList(cond.Ninit)
 +              s.condBranch(cond.Left, yes, mid, min8(likely, 0))
 +              s.startBlock(mid)
 +              s.condBranch(cond.Right, yes, no, likely)
 +              return
 +              // Note: if likely==-1, then both recursive calls pass -1.
 +              // If likely==1, then we don't have enough info to decide
 +              // the likelihood of the first branch.
 +      }
 +      if cond.Op == ONOT {
 +              s.stmtList(cond.Ninit)
 +              s.condBranch(cond.Left, no, yes, -likely)
 +              return
 +      }
 +      c := s.expr(cond)
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = c
 +      b.Likely = ssa.BranchPrediction(likely) // gc and ssa both use -1/0/+1 for likeliness
 +      b.AddEdgeTo(yes)
 +      b.AddEdgeTo(no)
 +}
 +
 +func (s *state) assign(left *Node, right *ssa.Value, wb bool) {
 +      if left.Op == ONAME && isblank(left) {
 +              return
 +      }
 +      t := left.Type
 +      dowidth(t)
 +      if right == nil {
 +              // right == nil means use the zero value of the assigned type.
 +              if !canSSA(left) {
 +                      // if we can't ssa this memory, treat it as just zeroing out the backing memory
 +                      addr := s.addr(left, false)
 +                      if left.Op == ONAME {
 +                              s.vars[&memVar] = s.newValue1A(ssa.OpVarDef, ssa.TypeMem, left, s.mem())
 +                      }
 +                      s.vars[&memVar] = s.newValue2I(ssa.OpZero, ssa.TypeMem, t.Size(), addr, s.mem())
 +                      return
 +              }
 +              right = s.zeroVal(t)
 +      }
 +      if left.Op == ONAME && canSSA(left) {
 +              // Update variable assignment.
 +              s.vars[left] = right
 +              s.addNamedValue(left, right)
 +              return
 +      }
 +      // not ssa-able.  Treat as a store.
 +      addr := s.addr(left, false)
 +      if left.Op == ONAME {
 +              s.vars[&memVar] = s.newValue1A(ssa.OpVarDef, ssa.TypeMem, left, s.mem())
 +      }
 +      s.vars[&memVar] = s.newValue3I(ssa.OpStore, ssa.TypeMem, t.Size(), addr, right, s.mem())
 +      if wb {
 +              s.insertWB(left.Type, addr, left.Lineno)
 +      }
 +}
 +
 +// zeroVal returns the zero value for type t.
 +func (s *state) zeroVal(t *Type) *ssa.Value {
 +      switch {
 +      case t.IsInteger():
 +              switch t.Size() {
 +              case 1:
 +                      return s.constInt8(t, 0)
 +              case 2:
 +                      return s.constInt16(t, 0)
 +              case 4:
 +                      return s.constInt32(t, 0)
 +              case 8:
 +                      return s.constInt64(t, 0)
 +              default:
 +                      s.Fatalf("bad sized integer type %s", t)
 +              }
 +      case t.IsFloat():
 +              switch t.Size() {
 +              case 4:
 +                      return s.constFloat32(t, 0)
 +              case 8:
 +                      return s.constFloat64(t, 0)
 +              default:
 +                      s.Fatalf("bad sized float type %s", t)
 +              }
 +      case t.IsComplex():
 +              switch t.Size() {
 +              case 8:
 +                      z := s.constFloat32(Types[TFLOAT32], 0)
 +                      return s.entryNewValue2(ssa.OpComplexMake, t, z, z)
 +              case 16:
 +                      z := s.constFloat64(Types[TFLOAT64], 0)
 +                      return s.entryNewValue2(ssa.OpComplexMake, t, z, z)
 +              default:
 +                      s.Fatalf("bad sized complex type %s", t)
 +              }
 +
 +      case t.IsString():
 +              return s.entryNewValue0A(ssa.OpConstString, t, "")
 +      case t.IsPtr():
 +              return s.entryNewValue0(ssa.OpConstNil, t)
 +      case t.IsBoolean():
 +              return s.constBool(false)
 +      case t.IsInterface():
 +              return s.entryNewValue0(ssa.OpConstInterface, t)
 +      case t.IsSlice():
 +              return s.entryNewValue0(ssa.OpConstSlice, t)
 +      }
 +      s.Unimplementedf("zero for type %v not implemented", t)
 +      return nil
 +}
 +
 +type callKind int8
 +
 +const (
 +      callNormal callKind = iota
 +      callDefer
 +      callGo
 +)
 +
 +func (s *state) call(n *Node, k callKind) *ssa.Value {
 +      var sym *Sym           // target symbol (if static)
 +      var closure *ssa.Value // ptr to closure to run (if dynamic)
 +      var codeptr *ssa.Value // ptr to target code (if dynamic)
 +      var rcvr *ssa.Value    // receiver to set
 +      fn := n.Left
 +      switch n.Op {
 +      case OCALLFUNC:
 +              if k == callNormal && fn.Op == ONAME && fn.Class == PFUNC {
 +                      sym = fn.Sym
 +                      break
 +              }
 +              closure = s.expr(fn)
 +              if closure == nil {
 +                      return nil // TODO: remove when expr always returns non-nil
 +              }
 +      case OCALLMETH:
 +              if fn.Op != ODOTMETH {
 +                      Fatalf("OCALLMETH: n.Left not an ODOTMETH: %v", fn)
 +              }
 +              if fn.Right.Op != ONAME {
 +                      Fatalf("OCALLMETH: n.Left.Right not a ONAME: %v", fn.Right)
 +              }
 +              if k == callNormal {
 +                      sym = fn.Right.Sym
 +                      break
 +              }
 +              n2 := *fn.Right
 +              n2.Class = PFUNC
 +              closure = s.expr(&n2)
 +              // Note: receiver is already assigned in n.List, so we don't
 +              // want to set it here.
 +      case OCALLINTER:
 +              if fn.Op != ODOTINTER {
 +                      Fatalf("OCALLINTER: n.Left not an ODOTINTER: %v", Oconv(int(fn.Op), 0))
 +              }
 +              i := s.expr(fn.Left)
 +              itab := s.newValue1(ssa.OpITab, Types[TUINTPTR], i)
 +              itabidx := fn.Xoffset + 3*int64(Widthptr) + 8 // offset of fun field in runtime.itab
 +              itab = s.newValue1I(ssa.OpOffPtr, Types[TUINTPTR], itabidx, itab)
 +              if k == callNormal {
 +                      codeptr = s.newValue2(ssa.OpLoad, Types[TUINTPTR], itab, s.mem())
 +              } else {
 +                      closure = itab
 +              }
 +              rcvr = s.newValue1(ssa.OpIData, Types[TUINTPTR], i)
 +      }
 +      dowidth(fn.Type)
 +      stksize := fn.Type.Argwid // includes receiver
 +
 +      // Run all argument assignments.  The arg slots have already
 +      // been offset by the appropriate amount (+2*widthptr for go/defer,
 +      // +widthptr for interface calls).
 +      // For OCALLMETH, the receiver is set in these statements.
 +      s.stmtList(n.List)
 +
 +      // Set receiver (for interface calls)
 +      if rcvr != nil {
 +              argStart := Ctxt.FixedFrameSize()
 +              if k != callNormal {
 +                      argStart += int64(2 * Widthptr)
 +              }
 +              addr := s.entryNewValue1I(ssa.OpOffPtr, Types[TUINTPTR], argStart, s.sp)
 +              s.vars[&memVar] = s.newValue3I(ssa.OpStore, ssa.TypeMem, int64(Widthptr), addr, rcvr, s.mem())
 +      }
 +
 +      // Defer/go args
 +      if k != callNormal {
 +              // Write argsize and closure (args to Newproc/Deferproc).
 +              argsize := s.constInt32(Types[TUINT32], int32(stksize))
 +              s.vars[&memVar] = s.newValue3I(ssa.OpStore, ssa.TypeMem, 4, s.sp, argsize, s.mem())
 +              addr := s.entryNewValue1I(ssa.OpOffPtr, Ptrto(Types[TUINTPTR]), int64(Widthptr), s.sp)
 +              s.vars[&memVar] = s.newValue3I(ssa.OpStore, ssa.TypeMem, int64(Widthptr), addr, closure, s.mem())
 +              stksize += 2 * int64(Widthptr)
 +      }
 +
 +      // call target
 +      bNext := s.f.NewBlock(ssa.BlockPlain)
 +      var call *ssa.Value
 +      switch {
 +      case k == callDefer:
 +              call = s.newValue1(ssa.OpDeferCall, ssa.TypeMem, s.mem())
 +      case k == callGo:
 +              call = s.newValue1(ssa.OpGoCall, ssa.TypeMem, s.mem())
 +      case closure != nil:
 +              codeptr = s.newValue2(ssa.OpLoad, Types[TUINTPTR], closure, s.mem())
 +              call = s.newValue3(ssa.OpClosureCall, ssa.TypeMem, codeptr, closure, s.mem())
 +      case codeptr != nil:
 +              call = s.newValue2(ssa.OpInterCall, ssa.TypeMem, codeptr, s.mem())
 +      case sym != nil:
 +              call = s.newValue1A(ssa.OpStaticCall, ssa.TypeMem, sym, s.mem())
 +      default:
 +              Fatalf("bad call type %s %v", opnames[n.Op], n)
 +      }
 +      call.AuxInt = stksize // Call operations carry the argsize of the callee along with them
 +
 +      // Finish call block
 +      s.vars[&memVar] = call
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockCall
 +      b.Control = call
 +      b.AddEdgeTo(bNext)
 +
 +      // Read result from stack at the start of the fallthrough block
 +      s.startBlock(bNext)
 +      var titer Iter
 +      fp := Structfirst(&titer, Getoutarg(n.Left.Type))
 +      if fp == nil || k != callNormal {
 +              // call has no return value. Continue with the next statement.
 +              return nil
 +      }
 +      a := s.entryNewValue1I(ssa.OpOffPtr, Ptrto(fp.Type), fp.Width, s.sp)
 +      return s.newValue2(ssa.OpLoad, fp.Type, a, call)
 +}
 +
 +// etypesign returns the signed-ness of e, for integer/pointer etypes.
 +// -1 means signed, +1 means unsigned, 0 means non-integer/non-pointer.
-                       if v == nil {
-                               if flag_race != 0 && n.String() == ".fp" {
-                                       s.Unimplementedf("race detector mishandles nodfp")
-                               }
-                               s.Fatalf("addr of undeclared ONAME %v. declared: %v", n, s.decladdrs)
++func etypesign(e EType) int8 {
 +      switch e {
 +      case TINT8, TINT16, TINT32, TINT64, TINT:
 +              return -1
 +      case TUINT8, TUINT16, TUINT32, TUINT64, TUINT, TUINTPTR, TUNSAFEPTR:
 +              return +1
 +      }
 +      return 0
 +}
 +
 +// lookupSymbol is used to retrieve the symbol (Extern, Arg or Auto) used for a particular node.
 +// This improves the effectiveness of cse by using the same Aux values for the
 +// same symbols.
 +func (s *state) lookupSymbol(n *Node, sym interface{}) interface{} {
 +      switch sym.(type) {
 +      default:
 +              s.Fatalf("sym %v is of uknown type %T", sym, sym)
 +      case *ssa.ExternSymbol, *ssa.ArgSymbol, *ssa.AutoSymbol:
 +              // these are the only valid types
 +      }
 +
 +      if lsym, ok := s.varsyms[n]; ok {
 +              return lsym
 +      } else {
 +              s.varsyms[n] = sym
 +              return sym
 +      }
 +}
 +
 +// addr converts the address of the expression n to SSA, adds it to s and returns the SSA result.
 +// The value that the returned Value represents is guaranteed to be non-nil.
 +// If bounded is true then this address does not require a nil check for its operand
 +// even if that would otherwise be implied.
 +func (s *state) addr(n *Node, bounded bool) *ssa.Value {
 +      t := Ptrto(n.Type)
 +      switch n.Op {
 +      case ONAME:
 +              switch n.Class {
 +              case PEXTERN:
 +                      // global variable
 +                      aux := s.lookupSymbol(n, &ssa.ExternSymbol{n.Type, n.Sym})
 +                      v := s.entryNewValue1A(ssa.OpAddr, t, aux, s.sb)
 +                      // TODO: Make OpAddr use AuxInt as well as Aux.
 +                      if n.Xoffset != 0 {
 +                              v = s.entryNewValue1I(ssa.OpOffPtr, v.Type, n.Xoffset, v)
 +                      }
 +                      return v
 +              case PPARAM:
 +                      // parameter slot
 +                      v := s.decladdrs[n]
-                       return v
++                      if v != nil {
++                              return v
 +                      }
-       // if writeBarrierEnabled {
++                      if n.String() == ".fp" {
++                              // Special arg that points to the frame pointer.
++                              // (Used by the race detector, others?)
++                              aux := s.lookupSymbol(n, &ssa.ArgSymbol{Typ: n.Type, Node: n})
++                              return s.entryNewValue1A(ssa.OpAddr, t, aux, s.sp)
++                      }
++                      s.Fatalf("addr of undeclared ONAME %v. declared: %v", n, s.decladdrs)
++                      return nil
 +              case PAUTO:
 +                      // We need to regenerate the address of autos
 +                      // at every use.  This prevents LEA instructions
 +                      // from occurring before the corresponding VarDef
 +                      // op and confusing the liveness analysis into thinking
 +                      // the variable is live at function entry.
 +                      // TODO: I'm not sure if this really works or we're just
 +                      // getting lucky.  We might need a real dependency edge
 +                      // between vardef and addr ops.
 +                      aux := &ssa.AutoSymbol{Typ: n.Type, Node: n}
 +                      return s.newValue1A(ssa.OpAddr, t, aux, s.sp)
 +              case PPARAMOUT: // Same as PAUTO -- cannot generate LEA early.
 +                      // ensure that we reuse symbols for out parameters so
 +                      // that cse works on their addresses
 +                      aux := s.lookupSymbol(n, &ssa.ArgSymbol{Typ: n.Type, Node: n})
 +                      return s.newValue1A(ssa.OpAddr, t, aux, s.sp)
 +              case PAUTO | PHEAP, PPARAM | PHEAP, PPARAMOUT | PHEAP, PPARAMREF:
 +                      return s.expr(n.Name.Heapaddr)
 +              default:
 +                      s.Unimplementedf("variable address class %v not implemented", n.Class)
 +                      return nil
 +              }
 +      case OINDREG:
 +              // indirect off a register
 +              // used for storing/loading arguments/returns to/from callees
 +              if int(n.Reg) != Thearch.REGSP {
 +                      s.Unimplementedf("OINDREG of non-SP register %s in addr: %v", obj.Rconv(int(n.Reg)), n)
 +                      return nil
 +              }
 +              return s.entryNewValue1I(ssa.OpOffPtr, t, n.Xoffset, s.sp)
 +      case OINDEX:
 +              if n.Left.Type.IsSlice() {
 +                      a := s.expr(n.Left)
 +                      i := s.expr(n.Right)
 +                      i = s.extendIndex(i)
 +                      len := s.newValue1(ssa.OpSliceLen, Types[TINT], a)
 +                      if !n.Bounded {
 +                              s.boundsCheck(i, len)
 +                      }
 +                      p := s.newValue1(ssa.OpSlicePtr, t, a)
 +                      return s.newValue2(ssa.OpPtrIndex, t, p, i)
 +              } else { // array
 +                      a := s.addr(n.Left, bounded)
 +                      i := s.expr(n.Right)
 +                      i = s.extendIndex(i)
 +                      len := s.constInt(Types[TINT], n.Left.Type.Bound)
 +                      if !n.Bounded {
 +                              s.boundsCheck(i, len)
 +                      }
 +                      return s.newValue2(ssa.OpPtrIndex, Ptrto(n.Left.Type.Type), a, i)
 +              }
 +      case OIND:
 +              p := s.expr(n.Left)
 +              if !bounded {
 +                      s.nilCheck(p)
 +              }
 +              return p
 +      case ODOT:
 +              p := s.addr(n.Left, bounded)
 +              return s.newValue2(ssa.OpAddPtr, t, p, s.constInt(Types[TINT], n.Xoffset))
 +      case ODOTPTR:
 +              p := s.expr(n.Left)
 +              if !bounded {
 +                      s.nilCheck(p)
 +              }
 +              return s.newValue2(ssa.OpAddPtr, t, p, s.constInt(Types[TINT], n.Xoffset))
 +      case OCLOSUREVAR:
 +              return s.newValue2(ssa.OpAddPtr, t,
 +                      s.entryNewValue0(ssa.OpGetClosurePtr, Ptrto(Types[TUINT8])),
 +                      s.constInt(Types[TINT], n.Xoffset))
 +      case OPARAM:
 +              p := n.Left
 +              if p.Op != ONAME || !(p.Class == PPARAM|PHEAP || p.Class == PPARAMOUT|PHEAP) {
 +                      s.Fatalf("OPARAM not of ONAME,{PPARAM,PPARAMOUT}|PHEAP, instead %s", nodedump(p, 0))
 +              }
 +
 +              // Recover original offset to address passed-in param value.
 +              original_p := *p
 +              original_p.Xoffset = n.Xoffset
 +              aux := &ssa.ArgSymbol{Typ: n.Type, Node: &original_p}
 +              return s.entryNewValue1A(ssa.OpAddr, t, aux, s.sp)
 +      case OCONVNOP:
 +              addr := s.addr(n.Left, bounded)
 +              return s.newValue1(ssa.OpCopy, t, addr) // ensure that addr has the right type
 +
 +      default:
 +              s.Unimplementedf("unhandled addr %v", Oconv(int(n.Op), 0))
 +              return nil
 +      }
 +}
 +
 +// canSSA reports whether n is SSA-able.
 +// n must be an ONAME.
 +func canSSA(n *Node) bool {
 +      if n.Op != ONAME {
 +              return false
 +      }
 +      if n.Addrtaken {
 +              return false
 +      }
 +      if n.Class&PHEAP != 0 {
 +              return false
 +      }
 +      switch n.Class {
 +      case PEXTERN, PPARAMOUT, PPARAMREF:
 +              return false
 +      }
 +      if n.Class == PPARAM && n.String() == ".this" {
 +              // wrappers generated by genwrapper need to update
 +              // the .this pointer in place.
 +              return false
 +      }
 +      return canSSAType(n.Type)
 +      // TODO: try to make more variables SSAable?
 +}
 +
 +// canSSA reports whether variables of type t are SSA-able.
 +func canSSAType(t *Type) bool {
 +      dowidth(t)
 +      if t.Width > int64(4*Widthptr) {
 +              // 4*Widthptr is an arbitrary constant.  We want it
 +              // to be at least 3*Widthptr so slices can be registerized.
 +              // Too big and we'll introduce too much register pressure.
 +              return false
 +      }
 +      switch t.Etype {
 +      case TARRAY:
 +              if Isslice(t) {
 +                      return true
 +              }
 +              // We can't do arrays because dynamic indexing is
 +              // not supported on SSA variables.
 +              // TODO: maybe allow if length is <=1?  All indexes
 +              // are constant?  Might be good for the arrays
 +              // introduced by the compiler for variadic functions.
 +              return false
 +      case TSTRUCT:
 +              if countfield(t) > 4 {
 +                      // 4 is an arbitrary constant.  Same reasoning
 +                      // as above, lots of small fields would waste
 +                      // register space needed by other values.
 +                      return false
 +              }
 +              for t1 := t.Type; t1 != nil; t1 = t1.Down {
 +                      if !canSSAType(t1.Type) {
 +                              return false
 +                      }
 +              }
 +              return false // until it is implemented
 +              //return true
 +      default:
 +              return true
 +      }
 +}
 +
 +// nilCheck generates nil pointer checking code.
 +// Starts a new block on return, unless nil checks are disabled.
 +// Used only for automatically inserted nil checks,
 +// not for user code like 'x != nil'.
 +func (s *state) nilCheck(ptr *ssa.Value) {
 +      if Disable_checknil != 0 {
 +              return
 +      }
 +      chk := s.newValue2(ssa.OpNilCheck, ssa.TypeVoid, ptr, s.mem())
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockCheck
 +      b.Control = chk
 +      bNext := s.f.NewBlock(ssa.BlockPlain)
 +      b.AddEdgeTo(bNext)
 +      s.startBlock(bNext)
 +}
 +
 +// boundsCheck generates bounds checking code.  Checks if 0 <= idx < len, branches to exit if not.
 +// Starts a new block on return.
 +func (s *state) boundsCheck(idx, len *ssa.Value) {
 +      if Debug['B'] != 0 {
 +              return
 +      }
 +      // TODO: convert index to full width?
 +      // TODO: if index is 64-bit and we're compiling to 32-bit, check that high 32 bits are zero.
 +
 +      // bounds check
 +      cmp := s.newValue2(ssa.OpIsInBounds, Types[TBOOL], idx, len)
 +      s.check(cmp, Panicindex)
 +}
 +
 +// sliceBoundsCheck generates slice bounds checking code.  Checks if 0 <= idx <= len, branches to exit if not.
 +// Starts a new block on return.
 +func (s *state) sliceBoundsCheck(idx, len *ssa.Value) {
 +      if Debug['B'] != 0 {
 +              return
 +      }
 +      // TODO: convert index to full width?
 +      // TODO: if index is 64-bit and we're compiling to 32-bit, check that high 32 bits are zero.
 +
 +      // bounds check
 +      cmp := s.newValue2(ssa.OpIsSliceInBounds, Types[TBOOL], idx, len)
 +      s.check(cmp, panicslice)
 +}
 +
 +// If cmp (a bool) is true, panic using the given function.
 +func (s *state) check(cmp *ssa.Value, fn *Node) {
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = cmp
 +      b.Likely = ssa.BranchLikely
 +      bNext := s.f.NewBlock(ssa.BlockPlain)
 +      line := s.peekLine()
 +      bPanic := s.panics[funcLine{fn, line}]
 +      if bPanic == nil {
 +              bPanic = s.f.NewBlock(ssa.BlockPlain)
 +              s.panics[funcLine{fn, line}] = bPanic
 +              s.startBlock(bPanic)
 +              // The panic call takes/returns memory to ensure that the right
 +              // memory state is observed if the panic happens.
 +              s.rtcall(fn, false, nil)
 +      }
 +      b.AddEdgeTo(bNext)
 +      b.AddEdgeTo(bPanic)
 +      s.startBlock(bNext)
 +}
 +
 +// rtcall issues a call to the given runtime function fn with the listed args.
 +// Returns a slice of results of the given result types.
 +// The call is added to the end of the current block.
 +// If returns is false, the block is marked as an exit block.
 +// If returns is true, the block is marked as a call block.  A new block
 +// is started to load the return values.
 +func (s *state) rtcall(fn *Node, returns bool, results []*Type, args ...*ssa.Value) []*ssa.Value {
 +      // Write args to the stack
 +      var off int64 // TODO: arch-dependent starting offset?
 +      for _, arg := range args {
 +              t := arg.Type
 +              off = Rnd(off, t.Alignment())
 +              ptr := s.sp
 +              if off != 0 {
 +                      ptr = s.newValue1I(ssa.OpOffPtr, Types[TUINTPTR], off, s.sp)
 +              }
 +              size := t.Size()
 +              s.vars[&memVar] = s.newValue3I(ssa.OpStore, ssa.TypeMem, size, ptr, arg, s.mem())
 +              off += size
 +      }
 +      off = Rnd(off, int64(Widthptr))
 +
 +      // Issue call
 +      call := s.newValue1A(ssa.OpStaticCall, ssa.TypeMem, fn.Sym, s.mem())
 +      s.vars[&memVar] = call
 +
 +      // Finish block
 +      b := s.endBlock()
 +      if !returns {
 +              b.Kind = ssa.BlockExit
 +              b.Control = call
 +              call.AuxInt = off
 +              if len(results) > 0 {
 +                      Fatalf("panic call can't have results")
 +              }
 +              return nil
 +      }
 +      b.Kind = ssa.BlockCall
 +      b.Control = call
 +      bNext := s.f.NewBlock(ssa.BlockPlain)
 +      b.AddEdgeTo(bNext)
 +      s.startBlock(bNext)
 +
 +      // Load results
 +      res := make([]*ssa.Value, len(results))
 +      for i, t := range results {
 +              off = Rnd(off, t.Alignment())
 +              ptr := s.sp
 +              if off != 0 {
 +                      ptr = s.newValue1I(ssa.OpOffPtr, Types[TUINTPTR], off, s.sp)
 +              }
 +              res[i] = s.newValue2(ssa.OpLoad, t, ptr, s.mem())
 +              off += t.Size()
 +      }
 +      off = Rnd(off, int64(Widthptr))
 +
 +      // Remember how much callee stack space we needed.
 +      call.AuxInt = off
 +
 +      return res
 +}
 +
 +// insertWB inserts a write barrier.  A value of type t has already
 +// been stored at location p.  Tell the runtime about this write.
 +// Note: there must be no GC suspension points between the write and
 +// the call that this function inserts.
 +func (s *state) insertWB(t *Type, p *ssa.Value, line int32) {
-       aux := &ssa.ExternSymbol{Types[TBOOL], syslook("writeBarrierEnabled", 0).Sym}
++      // if writeBarrier.enabled {
 +      //   typedmemmove_nostore(&t, p)
 +      // }
 +      bThen := s.f.NewBlock(ssa.BlockPlain)
 +
++      aux := &ssa.ExternSymbol{Types[TBOOL], syslook("writeBarrier", 0).Sym}
 +      flagaddr := s.newValue1A(ssa.OpAddr, Ptrto(Types[TBOOL]), aux, s.sb)
++      // TODO: select the .enabled field.  It is currently first, so not needed for now.
 +      flag := s.newValue2(ssa.OpLoad, Types[TBOOL], flagaddr, s.mem())
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Likely = ssa.BranchUnlikely
 +      b.Control = flag
 +      b.AddEdgeTo(bThen)
 +
 +      s.startBlock(bThen)
 +      // TODO: writebarrierptr_nostore if just one pointer word (or a few?)
 +      taddr := s.newValue1A(ssa.OpAddr, Types[TUINTPTR], &ssa.ExternSymbol{Types[TUINTPTR], typenamesym(t)}, s.sb)
 +      s.rtcall(typedmemmove_nostore, true, nil, taddr, p)
 +
 +      if Debug_wb > 0 {
 +              Warnl(int(line), "write barrier")
 +      }
 +
 +      b.AddEdgeTo(s.curBlock)
 +}
 +
 +// slice computes the slice v[i:j:k] and returns ptr, len, and cap of result.
 +// i,j,k may be nil, in which case they are set to their default value.
 +// t is a slice, ptr to array, or string type.
 +func (s *state) slice(t *Type, v, i, j, k *ssa.Value) (p, l, c *ssa.Value) {
 +      var elemtype *Type
 +      var ptrtype *Type
 +      var ptr *ssa.Value
 +      var len *ssa.Value
 +      var cap *ssa.Value
 +      zero := s.constInt(Types[TINT], 0)
 +      switch {
 +      case t.IsSlice():
 +              elemtype = t.Type
 +              ptrtype = Ptrto(elemtype)
 +              ptr = s.newValue1(ssa.OpSlicePtr, ptrtype, v)
 +              len = s.newValue1(ssa.OpSliceLen, Types[TINT], v)
 +              cap = s.newValue1(ssa.OpSliceCap, Types[TINT], v)
 +      case t.IsString():
 +              elemtype = Types[TUINT8]
 +              ptrtype = Ptrto(elemtype)
 +              ptr = s.newValue1(ssa.OpStringPtr, ptrtype, v)
 +              len = s.newValue1(ssa.OpStringLen, Types[TINT], v)
 +              cap = len
 +      case t.IsPtr():
 +              if !t.Type.IsArray() {
 +                      s.Fatalf("bad ptr to array in slice %v\n", t)
 +              }
 +              elemtype = t.Type.Type
 +              ptrtype = Ptrto(elemtype)
 +              s.nilCheck(v)
 +              ptr = v
 +              len = s.constInt(Types[TINT], t.Type.Bound)
 +              cap = len
 +      default:
 +              s.Fatalf("bad type in slice %v\n", t)
 +      }
 +
 +      // Set default values
 +      if i == nil {
 +              i = zero
 +      }
 +      if j == nil {
 +              j = len
 +      }
 +      if k == nil {
 +              k = cap
 +      }
 +
 +      // Panic if slice indices are not in bounds.
 +      s.sliceBoundsCheck(i, j)
 +      if j != k {
 +              s.sliceBoundsCheck(j, k)
 +      }
 +      if k != cap {
 +              s.sliceBoundsCheck(k, cap)
 +      }
 +
 +      // Generate the following code assuming that indexes are in bounds.
 +      // The conditional is to make sure that we don't generate a slice
 +      // that points to the next object in memory.
 +      // rlen = (Sub64 j i)
 +      // rcap = (Sub64 k i)
 +      // p = ptr
 +      // if rcap != 0 {
 +      //    p = (AddPtr ptr (Mul64 low (Const64 size)))
 +      // }
 +      // result = (SliceMake p size)
 +      subOp := s.ssaOp(OSUB, Types[TINT])
 +      neqOp := s.ssaOp(ONE, Types[TINT])
 +      mulOp := s.ssaOp(OMUL, Types[TINT])
 +      rlen := s.newValue2(subOp, Types[TINT], j, i)
 +      var rcap *ssa.Value
 +      switch {
 +      case t.IsString():
 +              // Capacity of the result is unimportant.  However, we use
 +              // rcap to test if we've generated a zero-length slice.
 +              // Use length of strings for that.
 +              rcap = rlen
 +      case j == k:
 +              rcap = rlen
 +      default:
 +              rcap = s.newValue2(subOp, Types[TINT], k, i)
 +      }
 +
 +      s.vars[&ptrVar] = ptr
 +
 +      // Generate code to test the resulting slice length.
 +      cmp := s.newValue2(neqOp, Types[TBOOL], rcap, s.constInt(Types[TINT], 0))
 +
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Likely = ssa.BranchLikely
 +      b.Control = cmp
 +
 +      // Generate code for non-zero length slice case.
 +      nz := s.f.NewBlock(ssa.BlockPlain)
 +      b.AddEdgeTo(nz)
 +      s.startBlock(nz)
 +      var inc *ssa.Value
 +      if elemtype.Width == 1 {
 +              inc = i
 +      } else {
 +              inc = s.newValue2(mulOp, Types[TINT], i, s.constInt(Types[TINT], elemtype.Width))
 +      }
 +      s.vars[&ptrVar] = s.newValue2(ssa.OpAddPtr, ptrtype, ptr, inc)
 +      s.endBlock()
 +
 +      // All done.
 +      merge := s.f.NewBlock(ssa.BlockPlain)
 +      b.AddEdgeTo(merge)
 +      nz.AddEdgeTo(merge)
 +      s.startBlock(merge)
 +      rptr := s.variable(&ptrVar, ptrtype)
 +      delete(s.vars, &ptrVar)
 +      return rptr, rlen, rcap
 +}
 +
 +type u2fcvtTab struct {
 +      geq, cvt2F, and, rsh, or, add ssa.Op
 +      one                           func(*state, ssa.Type, int64) *ssa.Value
 +}
 +
 +var u64_f64 u2fcvtTab = u2fcvtTab{
 +      geq:   ssa.OpGeq64,
 +      cvt2F: ssa.OpCvt64to64F,
 +      and:   ssa.OpAnd64,
 +      rsh:   ssa.OpRsh64Ux64,
 +      or:    ssa.OpOr64,
 +      add:   ssa.OpAdd64F,
 +      one:   (*state).constInt64,
 +}
 +
 +var u64_f32 u2fcvtTab = u2fcvtTab{
 +      geq:   ssa.OpGeq64,
 +      cvt2F: ssa.OpCvt64to32F,
 +      and:   ssa.OpAnd64,
 +      rsh:   ssa.OpRsh64Ux64,
 +      or:    ssa.OpOr64,
 +      add:   ssa.OpAdd32F,
 +      one:   (*state).constInt64,
 +}
 +
 +// Excess generality on a machine with 64-bit integer registers.
 +// Not used on AMD64.
 +var u32_f32 u2fcvtTab = u2fcvtTab{
 +      geq:   ssa.OpGeq32,
 +      cvt2F: ssa.OpCvt32to32F,
 +      and:   ssa.OpAnd32,
 +      rsh:   ssa.OpRsh32Ux32,
 +      or:    ssa.OpOr32,
 +      add:   ssa.OpAdd32F,
 +      one: func(s *state, t ssa.Type, x int64) *ssa.Value {
 +              return s.constInt32(t, int32(x))
 +      },
 +}
 +
 +func (s *state) uint64Tofloat64(n *Node, x *ssa.Value, ft, tt *Type) *ssa.Value {
 +      return s.uintTofloat(&u64_f64, n, x, ft, tt)
 +}
 +
 +func (s *state) uint64Tofloat32(n *Node, x *ssa.Value, ft, tt *Type) *ssa.Value {
 +      return s.uintTofloat(&u64_f32, n, x, ft, tt)
 +}
 +
 +func (s *state) uintTofloat(cvttab *u2fcvtTab, n *Node, x *ssa.Value, ft, tt *Type) *ssa.Value {
 +      // if x >= 0 {
 +      //    result = (floatY) x
 +      // } else {
 +      //        y = uintX(x) ; y = x & 1
 +      //        z = uintX(x) ; z = z >> 1
 +      //        z = z >> 1
 +      //        z = z | y
 +      //        result = floatY(z)
 +      //        result = result + result
 +      // }
 +      //
 +      // Code borrowed from old code generator.
 +      // What's going on: large 64-bit "unsigned" looks like
 +      // negative number to hardware's integer-to-float
 +      // conversion.  However, because the mantissa is only
 +      // 63 bits, we don't need the LSB, so instead we do an
 +      // unsigned right shift (divide by two), convert, and
 +      // double.  However, before we do that, we need to be
 +      // sure that we do not lose a "1" if that made the
 +      // difference in the resulting rounding.  Therefore, we
 +      // preserve it, and OR (not ADD) it back in.  The case
 +      // that matters is when the eleven discarded bits are
 +      // equal to 10000000001; that rounds up, and the 1 cannot
 +      // be lost else it would round down if the LSB of the
 +      // candidate mantissa is 0.
 +      cmp := s.newValue2(cvttab.geq, Types[TBOOL], x, s.zeroVal(ft))
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = cmp
 +      b.Likely = ssa.BranchLikely
 +
 +      bThen := s.f.NewBlock(ssa.BlockPlain)
 +      bElse := s.f.NewBlock(ssa.BlockPlain)
 +      bAfter := s.f.NewBlock(ssa.BlockPlain)
 +
 +      b.AddEdgeTo(bThen)
 +      s.startBlock(bThen)
 +      a0 := s.newValue1(cvttab.cvt2F, tt, x)
 +      s.vars[n] = a0
 +      s.endBlock()
 +      bThen.AddEdgeTo(bAfter)
 +
 +      b.AddEdgeTo(bElse)
 +      s.startBlock(bElse)
 +      one := cvttab.one(s, ft, 1)
 +      y := s.newValue2(cvttab.and, ft, x, one)
 +      z := s.newValue2(cvttab.rsh, ft, x, one)
 +      z = s.newValue2(cvttab.or, ft, z, y)
 +      a := s.newValue1(cvttab.cvt2F, tt, z)
 +      a1 := s.newValue2(cvttab.add, tt, a, a)
 +      s.vars[n] = a1
 +      s.endBlock()
 +      bElse.AddEdgeTo(bAfter)
 +
 +      s.startBlock(bAfter)
 +      return s.variable(n, n.Type)
 +}
 +
 +// referenceTypeBuiltin generates code for the len/cap builtins for maps and channels.
 +func (s *state) referenceTypeBuiltin(n *Node, x *ssa.Value) *ssa.Value {
 +      if !n.Left.Type.IsMap() && !n.Left.Type.IsChan() {
 +              s.Fatalf("node must be a map or a channel")
 +      }
 +      // if n == nil {
 +      //   return 0
 +      // } else {
 +      //   // len
 +      //   return *((*int)n)
 +      //   // cap
 +      //   return *(((*int)n)+1)
 +      // }
 +      lenType := n.Type
 +      nilValue := s.newValue0(ssa.OpConstNil, Types[TUINTPTR])
 +      cmp := s.newValue2(ssa.OpEqPtr, Types[TBOOL], x, nilValue)
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = cmp
 +      b.Likely = ssa.BranchUnlikely
 +
 +      bThen := s.f.NewBlock(ssa.BlockPlain)
 +      bElse := s.f.NewBlock(ssa.BlockPlain)
 +      bAfter := s.f.NewBlock(ssa.BlockPlain)
 +
 +      // length/capacity of a nil map/chan is zero
 +      b.AddEdgeTo(bThen)
 +      s.startBlock(bThen)
 +      s.vars[n] = s.zeroVal(lenType)
 +      s.endBlock()
 +      bThen.AddEdgeTo(bAfter)
 +
 +      b.AddEdgeTo(bElse)
 +      s.startBlock(bElse)
 +      if n.Op == OLEN {
 +              // length is stored in the first word for map/chan
 +              s.vars[n] = s.newValue2(ssa.OpLoad, lenType, x, s.mem())
 +      } else if n.Op == OCAP {
 +              // capacity is stored in the second word for chan
 +              sw := s.newValue1I(ssa.OpOffPtr, lenType.PtrTo(), lenType.Width, x)
 +              s.vars[n] = s.newValue2(ssa.OpLoad, lenType, sw, s.mem())
 +      } else {
 +              s.Fatalf("op must be OLEN or OCAP")
 +      }
 +      s.endBlock()
 +      bElse.AddEdgeTo(bAfter)
 +
 +      s.startBlock(bAfter)
 +      return s.variable(n, lenType)
 +}
 +
 +type f2uCvtTab struct {
 +      ltf, cvt2U, subf ssa.Op
 +      value            func(*state, ssa.Type, float64) *ssa.Value
 +}
 +
 +var f32_u64 f2uCvtTab = f2uCvtTab{
 +      ltf:   ssa.OpLess32F,
 +      cvt2U: ssa.OpCvt32Fto64,
 +      subf:  ssa.OpSub32F,
 +      value: (*state).constFloat32,
 +}
 +
 +var f64_u64 f2uCvtTab = f2uCvtTab{
 +      ltf:   ssa.OpLess64F,
 +      cvt2U: ssa.OpCvt64Fto64,
 +      subf:  ssa.OpSub64F,
 +      value: (*state).constFloat64,
 +}
 +
 +func (s *state) float32ToUint64(n *Node, x *ssa.Value, ft, tt *Type) *ssa.Value {
 +      return s.floatToUint(&f32_u64, n, x, ft, tt)
 +}
 +func (s *state) float64ToUint64(n *Node, x *ssa.Value, ft, tt *Type) *ssa.Value {
 +      return s.floatToUint(&f64_u64, n, x, ft, tt)
 +}
 +
 +func (s *state) floatToUint(cvttab *f2uCvtTab, n *Node, x *ssa.Value, ft, tt *Type) *ssa.Value {
 +      // if x < 9223372036854775808.0 {
 +      //      result = uintY(x)
 +      // } else {
 +      //      y = x - 9223372036854775808.0
 +      //      z = uintY(y)
 +      //      result = z | -9223372036854775808
 +      // }
 +      twoToThe63 := cvttab.value(s, ft, 9223372036854775808.0)
 +      cmp := s.newValue2(cvttab.ltf, Types[TBOOL], x, twoToThe63)
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = cmp
 +      b.Likely = ssa.BranchLikely
 +
 +      bThen := s.f.NewBlock(ssa.BlockPlain)
 +      bElse := s.f.NewBlock(ssa.BlockPlain)
 +      bAfter := s.f.NewBlock(ssa.BlockPlain)
 +
 +      b.AddEdgeTo(bThen)
 +      s.startBlock(bThen)
 +      a0 := s.newValue1(cvttab.cvt2U, tt, x)
 +      s.vars[n] = a0
 +      s.endBlock()
 +      bThen.AddEdgeTo(bAfter)
 +
 +      b.AddEdgeTo(bElse)
 +      s.startBlock(bElse)
 +      y := s.newValue2(cvttab.subf, ft, x, twoToThe63)
 +      y = s.newValue1(cvttab.cvt2U, tt, y)
 +      z := s.constInt64(tt, -9223372036854775808)
 +      a1 := s.newValue2(ssa.OpOr64, tt, y, z)
 +      s.vars[n] = a1
 +      s.endBlock()
 +      bElse.AddEdgeTo(bAfter)
 +
 +      s.startBlock(bAfter)
 +      return s.variable(n, n.Type)
 +}
 +
 +// ifaceType returns the value for the word containing the type.
 +// n is the node for the interface expression.
 +// v is the corresponding value.
 +func (s *state) ifaceType(n *Node, v *ssa.Value) *ssa.Value {
 +      byteptr := Ptrto(Types[TUINT8]) // type used in runtime prototypes for runtime type (*byte)
 +
 +      if isnilinter(n.Type) {
 +              // Have *eface. The type is the first word in the struct.
 +              return s.newValue1(ssa.OpITab, byteptr, v)
 +      }
 +
 +      // Have *iface.
 +      // The first word in the struct is the *itab.
 +      // If the *itab is nil, return 0.
 +      // Otherwise, the second word in the *itab is the type.
 +
 +      tab := s.newValue1(ssa.OpITab, byteptr, v)
 +      s.vars[&typVar] = tab
 +      isnonnil := s.newValue2(ssa.OpNeqPtr, Types[TBOOL], tab, s.entryNewValue0(ssa.OpConstNil, byteptr))
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = isnonnil
 +      b.Likely = ssa.BranchLikely
 +
 +      bLoad := s.f.NewBlock(ssa.BlockPlain)
 +      bEnd := s.f.NewBlock(ssa.BlockPlain)
 +
 +      b.AddEdgeTo(bLoad)
 +      b.AddEdgeTo(bEnd)
 +      bLoad.AddEdgeTo(bEnd)
 +
 +      s.startBlock(bLoad)
 +      off := s.newValue1I(ssa.OpOffPtr, byteptr, int64(Widthptr), tab)
 +      s.vars[&typVar] = s.newValue2(ssa.OpLoad, byteptr, off, s.mem())
 +      s.endBlock()
 +
 +      s.startBlock(bEnd)
 +      typ := s.variable(&typVar, byteptr)
 +      delete(s.vars, &typVar)
 +      return typ
 +}
 +
 +// dottype generates SSA for a type assertion node.
 +// commaok indicates whether to panic or return a bool.
 +// If commaok is false, resok will be nil.
 +func (s *state) dottype(n *Node, commaok bool) (res, resok *ssa.Value) {
 +      iface := s.expr(n.Left)
 +      typ := s.ifaceType(n.Left, iface)  // actual concrete type
 +      target := s.expr(typename(n.Type)) // target type
 +      if !isdirectiface(n.Type) {
 +              // walk rewrites ODOTTYPE/OAS2DOTTYPE into runtime calls except for this case.
 +              Fatalf("dottype needs a direct iface type %s", n.Type)
 +      }
 +
 +      if Debug_typeassert > 0 {
 +              Warnl(int(n.Lineno), "type assertion inlined")
 +      }
 +
 +      // TODO:  If we have a nonempty interface and its itab field is nil,
 +      // then this test is redundant and ifaceType should just branch directly to bFail.
 +      cond := s.newValue2(ssa.OpEqPtr, Types[TBOOL], typ, target)
 +      b := s.endBlock()
 +      b.Kind = ssa.BlockIf
 +      b.Control = cond
 +      b.Likely = ssa.BranchLikely
 +
 +      byteptr := Ptrto(Types[TUINT8])
 +
 +      bOk := s.f.NewBlock(ssa.BlockPlain)
 +      bFail := s.f.NewBlock(ssa.BlockPlain)
 +      b.AddEdgeTo(bOk)
 +      b.AddEdgeTo(bFail)
 +
 +      if !commaok {
 +              // on failure, panic by calling panicdottype
 +              s.startBlock(bFail)
 +              taddr := s.newValue1A(ssa.OpAddr, byteptr, &ssa.ExternSymbol{byteptr, typenamesym(n.Left.Type)}, s.sb)
 +              s.rtcall(panicdottype, false, nil, typ, target, taddr)
 +
 +              // on success, return idata field
 +              s.startBlock(bOk)
 +              return s.newValue1(ssa.OpIData, n.Type, iface), nil
 +      }
 +
 +      // commaok is the more complicated case because we have
 +      // a control flow merge point.
 +      bEnd := s.f.NewBlock(ssa.BlockPlain)
 +
 +      // type assertion succeeded
 +      s.startBlock(bOk)
 +      s.vars[&idataVar] = s.newValue1(ssa.OpIData, n.Type, iface)
 +      s.vars[&okVar] = s.constBool(true)
 +      s.endBlock()
 +      bOk.AddEdgeTo(bEnd)
 +
 +      // type assertion failed
 +      s.startBlock(bFail)
 +      s.vars[&idataVar] = s.entryNewValue0(ssa.OpConstNil, byteptr)
 +      s.vars[&okVar] = s.constBool(false)
 +      s.endBlock()
 +      bFail.AddEdgeTo(bEnd)
 +
 +      // merge point
 +      s.startBlock(bEnd)
 +      res = s.variable(&idataVar, byteptr)
 +      resok = s.variable(&okVar, Types[TBOOL])
 +      delete(s.vars, &idataVar)
 +      delete(s.vars, &okVar)
 +      return res, resok
 +}
 +
 +// checkgoto checks that a goto from from to to does not
 +// jump into a block or jump over variable declarations.
 +// It is a copy of checkgoto in the pre-SSA backend,
 +// modified only for line number handling.
 +// TODO: document how this works and why it is designed the way it is.
 +func (s *state) checkgoto(from *Node, to *Node) {
 +      if from.Sym == to.Sym {
 +              return
 +      }
 +
 +      nf := 0
 +      for fs := from.Sym; fs != nil; fs = fs.Link {
 +              nf++
 +      }
 +      nt := 0
 +      for fs := to.Sym; fs != nil; fs = fs.Link {
 +              nt++
 +      }
 +      fs := from.Sym
 +      for ; nf > nt; nf-- {
 +              fs = fs.Link
 +      }
 +      if fs != to.Sym {
 +              // decide what to complain about.
 +              // prefer to complain about 'into block' over declarations,
 +              // so scan backward to find most recent block or else dcl.
 +              var block *Sym
 +
 +              var dcl *Sym
 +              ts := to.Sym
 +              for ; nt > nf; nt-- {
 +                      if ts.Pkg == nil {
 +                              block = ts
 +                      } else {
 +                              dcl = ts
 +                      }
 +                      ts = ts.Link
 +              }
 +
 +              for ts != fs {
 +                      if ts.Pkg == nil {
 +                              block = ts
 +                      } else {
 +                              dcl = ts
 +                      }
 +                      ts = ts.Link
 +                      fs = fs.Link
 +              }
 +
 +              lno := int(from.Left.Lineno)
 +              if block != nil {
 +                      yyerrorl(lno, "goto %v jumps into block starting at %v", from.Left.Sym, Ctxt.Line(int(block.Lastlineno)))
 +              } else {
 +                      yyerrorl(lno, "goto %v jumps over declaration of %v at %v", from.Left.Sym, dcl, Ctxt.Line(int(dcl.Lastlineno)))
 +              }
 +      }
 +}
 +
 +// variable returns the value of a variable at the current location.
 +func (s *state) variable(name *Node, t ssa.Type) *ssa.Value {
 +      v := s.vars[name]
 +      if v == nil {
 +              // TODO: get type?  Take Sym as arg?
 +              v = s.newValue0A(ssa.OpFwdRef, t, name)
 +              s.vars[name] = v
 +      }
 +      return v
 +}
 +
 +func (s *state) mem() *ssa.Value {
 +      return s.variable(&memVar, ssa.TypeMem)
 +}
 +
 +func (s *state) linkForwardReferences() {
 +      // Build ssa graph.  Each variable on its first use in a basic block
 +      // leaves a FwdRef in that block representing the incoming value
 +      // of that variable.  This function links that ref up with possible definitions,
 +      // inserting Phi values as needed.  This is essentially the algorithm
 +      // described by Brau, Buchwald, Hack, Leißa, Mallon, and Zwinkau:
 +      // http://pp.info.uni-karlsruhe.de/uploads/publikationen/braun13cc.pdf
 +      for _, b := range s.f.Blocks {
 +              for _, v := range b.Values {
 +                      if v.Op != ssa.OpFwdRef {
 +                              continue
 +                      }
 +                      name := v.Aux.(*Node)
 +                      v.Op = ssa.OpCopy
 +                      v.Aux = nil
 +                      v.SetArgs1(s.lookupVarIncoming(b, v.Type, name))
 +              }
 +      }
 +}
 +
 +// lookupVarIncoming finds the variable's value at the start of block b.
 +func (s *state) lookupVarIncoming(b *ssa.Block, t ssa.Type, name *Node) *ssa.Value {
 +      // TODO(khr): have lookupVarIncoming overwrite the fwdRef or copy it
 +      // will be used in, instead of having the result used in a copy value.
 +      if b == s.f.Entry {
 +              if name == &memVar {
 +                      return s.startmem
 +              }
 +              if canSSA(name) {
 +                      v := s.entryNewValue0A(ssa.OpArg, t, name)
 +                      // v starts with AuxInt == 0.
 +                      s.addNamedValue(name, v)
 +                      return v
 +              }
 +              // variable is live at the entry block.  Load it.
 +              addr := s.decladdrs[name]
 +              if addr == nil {
 +                      // TODO: closure args reach here.
 +                      s.Unimplementedf("unhandled closure arg %s at entry to function %s", name, b.Func.Name)
 +              }
 +              if _, ok := addr.Aux.(*ssa.ArgSymbol); !ok {
 +                      s.Fatalf("variable live at start of function %s is not an argument %s", b.Func.Name, name)
 +              }
 +              return s.entryNewValue2(ssa.OpLoad, t, addr, s.startmem)
 +      }
 +      var vals []*ssa.Value
 +      for _, p := range b.Preds {
 +              vals = append(vals, s.lookupVarOutgoing(p, t, name))
 +      }
 +      if len(vals) == 0 {
 +              // This block is dead; we have no predecessors and we're not the entry block.
 +              // It doesn't matter what we use here as long as it is well-formed,
 +              // so use the default/zero value.
 +              if name == &memVar {
 +                      return s.startmem
 +              }
 +              return s.zeroVal(name.Type)
 +      }
 +      v0 := vals[0]
 +      for i := 1; i < len(vals); i++ {
 +              if vals[i] != v0 {
 +                      // need a phi value
 +                      v := b.NewValue0(s.peekLine(), ssa.OpPhi, t)
 +                      v.AddArgs(vals...)
 +                      s.addNamedValue(name, v)
 +                      return v
 +              }
 +      }
 +      return v0
 +}
 +
 +// lookupVarOutgoing finds the variable's value at the end of block b.
 +func (s *state) lookupVarOutgoing(b *ssa.Block, t ssa.Type, name *Node) *ssa.Value {
 +      m := s.defvars[b.ID]
 +      if v, ok := m[name]; ok {
 +              return v
 +      }
 +      // The variable is not defined by b and we haven't
 +      // looked it up yet.  Generate v, a copy value which
 +      // will be the outgoing value of the variable.  Then
 +      // look up w, the incoming value of the variable.
 +      // Make v = copy(w).  We need the extra copy to
 +      // prevent infinite recursion when looking up the
 +      // incoming value of the variable.
 +      v := b.NewValue0(s.peekLine(), ssa.OpCopy, t)
 +      m[name] = v
 +      v.AddArg(s.lookupVarIncoming(b, t, name))
 +      return v
 +}
 +
 +// TODO: the above mutually recursive functions can lead to very deep stacks.  Fix that.
 +
 +func (s *state) addNamedValue(n *Node, v *ssa.Value) {
 +      if n.Class == Pxxx {
 +              // Don't track our dummy nodes (&memVar etc.).
 +              return
 +      }
 +      if n.Sym == nil {
 +              // TODO: What the heck is this?
 +              return
 +      }
 +      if strings.HasPrefix(n.Sym.Name, "autotmp_") {
 +              // Don't track autotmp_ variables.
 +              return
 +      }
 +      if n.Class == PAUTO && (v.Type.IsString() || v.Type.IsSlice() || v.Type.IsInterface()) {
 +              // TODO: can't handle auto compound objects with pointers yet.
 +              // The live variable analysis barfs because we don't put VARDEF
 +              // pseudos in the right place when we spill to these nodes.
 +              return
 +      }
 +      if n.Class == PAUTO && n.Xoffset != 0 {
 +              s.Fatalf("AUTO var with offset %s %d", n, n.Xoffset)
 +      }
 +      loc := ssa.LocalSlot{N: n, Type: n.Type, Off: 0}
 +      values, ok := s.f.NamedValues[loc]
 +      if !ok {
 +              s.f.Names = append(s.f.Names, loc)
 +      }
 +      s.f.NamedValues[loc] = append(values, v)
 +}
 +
 +// an unresolved branch
 +type branch struct {
 +      p *obj.Prog  // branch instruction
 +      b *ssa.Block // target
 +}
 +
 +type genState struct {
 +      // branches remembers all the branch instructions we've seen
 +      // and where they would like to go.
 +      branches []branch
 +
 +      // bstart remembers where each block starts (indexed by block ID)
 +      bstart []*obj.Prog
 +
 +      // deferBranches remembers all the defer branches we've seen.
 +      deferBranches []*obj.Prog
 +
 +      // deferTarget remembers the (last) deferreturn call site.
 +      deferTarget *obj.Prog
 +}
 +
 +// genssa appends entries to ptxt for each instruction in f.
 +// gcargs and gclocals are filled in with pointer maps for the frame.
 +func genssa(f *ssa.Func, ptxt *obj.Prog, gcargs, gclocals *Sym) {
 +      var s genState
 +
 +      e := f.Config.Frontend().(*ssaExport)
 +      // We're about to emit a bunch of Progs.
 +      // Since the only way to get here is to explicitly request it,
 +      // just fail on unimplemented instead of trying to unwind our mess.
 +      e.mustImplement = true
 +
 +      // Remember where each block starts.
 +      s.bstart = make([]*obj.Prog, f.NumBlocks())
 +
 +      var valueProgs map[*obj.Prog]*ssa.Value
 +      var blockProgs map[*obj.Prog]*ssa.Block
 +      const logProgs = true
 +      if logProgs {
 +              valueProgs = make(map[*obj.Prog]*ssa.Value, f.NumValues())
 +              blockProgs = make(map[*obj.Prog]*ssa.Block, f.NumBlocks())
 +              f.Logf("genssa %s\n", f.Name)
 +              blockProgs[Pc] = f.Blocks[0]
 +      }
 +
 +      // Emit basic blocks
 +      for i, b := range f.Blocks {
 +              s.bstart[b.ID] = Pc
 +              // Emit values in block
 +              for _, v := range b.Values {
 +                      x := Pc
 +                      s.genValue(v)
 +                      if logProgs {
 +                              for ; x != Pc; x = x.Link {
 +                                      valueProgs[x] = v
 +                              }
 +                      }
 +              }
 +              // Emit control flow instructions for block
 +              var next *ssa.Block
 +              if i < len(f.Blocks)-1 {
 +                      next = f.Blocks[i+1]
 +              }
 +              x := Pc
 +              s.genBlock(b, next)
 +              if logProgs {
 +                      for ; x != Pc; x = x.Link {
 +                              blockProgs[x] = b
 +                      }
 +              }
 +      }
 +
 +      // Resolve branches
 +      for _, br := range s.branches {
 +              br.p.To.Val = s.bstart[br.b.ID]
 +      }
 +      if s.deferBranches != nil && s.deferTarget == nil {
 +              // This can happen when the function has a defer but
 +              // no return (because it has an infinite loop).
 +              s.deferReturn()
 +              Prog(obj.ARET)
 +      }
 +      for _, p := range s.deferBranches {
 +              p.To.Val = s.deferTarget
 +      }
 +
 +      if logProgs {
 +              for p := ptxt; p != nil; p = p.Link {
 +                      var s string
 +                      if v, ok := valueProgs[p]; ok {
 +                              s = v.String()
 +                      } else if b, ok := blockProgs[p]; ok {
 +                              s = b.String()
 +                      } else {
 +                              s = "   " // most value and branch strings are 2-3 characters long
 +                      }
 +                      f.Logf("%s\t%s\n", s, p)
 +              }
 +              if f.Config.HTML != nil {
 +                      saved := ptxt.Ctxt.LineHist.PrintFilenameOnly
 +                      ptxt.Ctxt.LineHist.PrintFilenameOnly = true
 +                      var buf bytes.Buffer
 +                      buf.WriteString("<code>")
 +                      buf.WriteString("<dl class=\"ssa-gen\">")
 +                      for p := ptxt; p != nil; p = p.Link {
 +                              buf.WriteString("<dt class=\"ssa-prog-src\">")
 +                              if v, ok := valueProgs[p]; ok {
 +                                      buf.WriteString(v.HTML())
 +                              } else if b, ok := blockProgs[p]; ok {
 +                                      buf.WriteString(b.HTML())
 +                              }
 +                              buf.WriteString("</dt>")
 +                              buf.WriteString("<dd class=\"ssa-prog\">")
 +                              buf.WriteString(html.EscapeString(p.String()))
 +                              buf.WriteString("</dd>")
 +                              buf.WriteString("</li>")
 +                      }
 +                      buf.WriteString("</dl>")
 +                      buf.WriteString("</code>")
 +                      f.Config.HTML.WriteColumn("genssa", buf.String())
 +                      ptxt.Ctxt.LineHist.PrintFilenameOnly = saved
 +              }
 +      }
 +
 +      // Emit static data
 +      if f.StaticData != nil {
 +              for _, n := range f.StaticData.([]*Node) {
 +                      if !gen_as_init(n, false) {
 +                              Fatalf("non-static data marked as static: %v\n\n", n, f)
 +                      }
 +              }
 +      }
 +
 +      // Allocate stack frame
 +      allocauto(ptxt)
 +
 +      // Generate gc bitmaps.
 +      liveness(Curfn, ptxt, gcargs, gclocals)
 +      gcsymdup(gcargs)
 +      gcsymdup(gclocals)
 +
 +      // Add frame prologue.  Zero ambiguously live variables.
 +      Thearch.Defframe(ptxt)
 +      if Debug['f'] != 0 {
 +              frame(0)
 +      }
 +
 +      // Remove leftover instrumentation from the instruction stream.
 +      removevardef(ptxt)
 +
 +      f.Config.HTML.Close()
 +}
 +
 +// opregreg emits instructions for
 +//     dest := dest(To) op src(From)
 +// and also returns the created obj.Prog so it
 +// may be further adjusted (offset, scale, etc).
 +func opregreg(op int, dest, src int16) *obj.Prog {
 +      p := Prog(op)
 +      p.From.Type = obj.TYPE_REG
 +      p.To.Type = obj.TYPE_REG
 +      p.To.Reg = dest
 +      p.From.Reg = src
 +      return p
 +}
 +
 +func (s *genState) genValue(v *ssa.Value) {
 +      lineno = v.Line
 +      switch v.Op {
 +      case ssa.OpAMD64ADDQ:
 +              // TODO: use addq instead of leaq if target is in the right register.
 +              p := Prog(x86.ALEAQ)
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              p.From.Scale = 1
 +              p.From.Index = regnum(v.Args[1])
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64ADDL:
 +              p := Prog(x86.ALEAL)
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              p.From.Scale = 1
 +              p.From.Index = regnum(v.Args[1])
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64ADDW:
 +              p := Prog(x86.ALEAW)
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              p.From.Scale = 1
 +              p.From.Index = regnum(v.Args[1])
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      // 2-address opcode arithmetic, symmetric
 +      case ssa.OpAMD64ADDB, ssa.OpAMD64ADDSS, ssa.OpAMD64ADDSD,
 +              ssa.OpAMD64ANDQ, ssa.OpAMD64ANDL, ssa.OpAMD64ANDW, ssa.OpAMD64ANDB,
 +              ssa.OpAMD64ORQ, ssa.OpAMD64ORL, ssa.OpAMD64ORW, ssa.OpAMD64ORB,
 +              ssa.OpAMD64XORQ, ssa.OpAMD64XORL, ssa.OpAMD64XORW, ssa.OpAMD64XORB,
 +              ssa.OpAMD64MULQ, ssa.OpAMD64MULL, ssa.OpAMD64MULW, ssa.OpAMD64MULB,
 +              ssa.OpAMD64MULSS, ssa.OpAMD64MULSD, ssa.OpAMD64PXOR:
 +              r := regnum(v)
 +              x := regnum(v.Args[0])
 +              y := regnum(v.Args[1])
 +              if x != r && y != r {
 +                      opregreg(regMoveByTypeAMD64(v.Type), r, x)
 +                      x = r
 +              }
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = r
 +              if x == r {
 +                      p.From.Reg = y
 +              } else {
 +                      p.From.Reg = x
 +              }
 +      // 2-address opcode arithmetic, not symmetric
 +      case ssa.OpAMD64SUBQ, ssa.OpAMD64SUBL, ssa.OpAMD64SUBW, ssa.OpAMD64SUBB:
 +              r := regnum(v)
 +              x := regnum(v.Args[0])
 +              y := regnum(v.Args[1])
 +              var neg bool
 +              if y == r {
 +                      // compute -(y-x) instead
 +                      x, y = y, x
 +                      neg = true
 +              }
 +              if x != r {
 +                      opregreg(regMoveByTypeAMD64(v.Type), r, x)
 +              }
 +              opregreg(v.Op.Asm(), r, y)
 +
 +              if neg {
 +                      p := Prog(x86.ANEGQ) // TODO: use correct size?  This is mostly a hack until regalloc does 2-address correctly
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +              }
 +      case ssa.OpAMD64SUBSS, ssa.OpAMD64SUBSD, ssa.OpAMD64DIVSS, ssa.OpAMD64DIVSD:
 +              r := regnum(v)
 +              x := regnum(v.Args[0])
 +              y := regnum(v.Args[1])
 +              if y == r && x != r {
 +                      // r/y := x op r/y, need to preserve x and rewrite to
 +                      // r/y := r/y op x15
 +                      x15 := int16(x86.REG_X15)
 +                      // register move y to x15
 +                      // register move x to y
 +                      // rename y with x15
 +                      opregreg(regMoveByTypeAMD64(v.Type), x15, y)
 +                      opregreg(regMoveByTypeAMD64(v.Type), r, x)
 +                      y = x15
 +              } else if x != r {
 +                      opregreg(regMoveByTypeAMD64(v.Type), r, x)
 +              }
 +              opregreg(v.Op.Asm(), r, y)
 +
 +      case ssa.OpAMD64DIVQ, ssa.OpAMD64DIVL, ssa.OpAMD64DIVW,
 +              ssa.OpAMD64DIVQU, ssa.OpAMD64DIVLU, ssa.OpAMD64DIVWU,
 +              ssa.OpAMD64MODQ, ssa.OpAMD64MODL, ssa.OpAMD64MODW,
 +              ssa.OpAMD64MODQU, ssa.OpAMD64MODLU, ssa.OpAMD64MODWU:
 +
 +              // Arg[0] is already in AX as it's the only register we allow
 +              // and AX is the only output
 +              x := regnum(v.Args[1])
 +
 +              // CPU faults upon signed overflow, which occurs when most
 +              // negative int is divided by -1.
 +              var j *obj.Prog
 +              if v.Op == ssa.OpAMD64DIVQ || v.Op == ssa.OpAMD64DIVL ||
 +                      v.Op == ssa.OpAMD64DIVW || v.Op == ssa.OpAMD64MODQ ||
 +                      v.Op == ssa.OpAMD64MODL || v.Op == ssa.OpAMD64MODW {
 +
 +                      var c *obj.Prog
 +                      switch v.Op {
 +                      case ssa.OpAMD64DIVQ, ssa.OpAMD64MODQ:
 +                              c = Prog(x86.ACMPQ)
 +                              j = Prog(x86.AJEQ)
 +                              // go ahead and sign extend to save doing it later
 +                              Prog(x86.ACQO)
 +
 +                      case ssa.OpAMD64DIVL, ssa.OpAMD64MODL:
 +                              c = Prog(x86.ACMPL)
 +                              j = Prog(x86.AJEQ)
 +                              Prog(x86.ACDQ)
 +
 +                      case ssa.OpAMD64DIVW, ssa.OpAMD64MODW:
 +                              c = Prog(x86.ACMPW)
 +                              j = Prog(x86.AJEQ)
 +                              Prog(x86.ACWD)
 +                      }
 +                      c.From.Type = obj.TYPE_REG
 +                      c.From.Reg = x
 +                      c.To.Type = obj.TYPE_CONST
 +                      c.To.Offset = -1
 +
 +                      j.To.Type = obj.TYPE_BRANCH
 +
 +              }
 +
 +              // for unsigned ints, we sign extend by setting DX = 0
 +              // signed ints were sign extended above
 +              if v.Op == ssa.OpAMD64DIVQU || v.Op == ssa.OpAMD64MODQU ||
 +                      v.Op == ssa.OpAMD64DIVLU || v.Op == ssa.OpAMD64MODLU ||
 +                      v.Op == ssa.OpAMD64DIVWU || v.Op == ssa.OpAMD64MODWU {
 +                      c := Prog(x86.AXORQ)
 +                      c.From.Type = obj.TYPE_REG
 +                      c.From.Reg = x86.REG_DX
 +                      c.To.Type = obj.TYPE_REG
 +                      c.To.Reg = x86.REG_DX
 +              }
 +
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = x
 +
 +              // signed division, rest of the check for -1 case
 +              if j != nil {
 +                      j2 := Prog(obj.AJMP)
 +                      j2.To.Type = obj.TYPE_BRANCH
 +
 +                      var n *obj.Prog
 +                      if v.Op == ssa.OpAMD64DIVQ || v.Op == ssa.OpAMD64DIVL ||
 +                              v.Op == ssa.OpAMD64DIVW {
 +                              // n * -1 = -n
 +                              n = Prog(x86.ANEGQ)
 +                              n.To.Type = obj.TYPE_REG
 +                              n.To.Reg = x86.REG_AX
 +                      } else {
 +                              // n % -1 == 0
 +                              n = Prog(x86.AXORQ)
 +                              n.From.Type = obj.TYPE_REG
 +                              n.From.Reg = x86.REG_DX
 +                              n.To.Type = obj.TYPE_REG
 +                              n.To.Reg = x86.REG_DX
 +                      }
 +
 +                      j.To.Val = n
 +                      j2.To.Val = Pc
 +              }
 +
 +      case ssa.OpAMD64HMULL, ssa.OpAMD64HMULW, ssa.OpAMD64HMULB,
 +              ssa.OpAMD64HMULLU, ssa.OpAMD64HMULWU, ssa.OpAMD64HMULBU:
 +              // the frontend rewrites constant division by 8/16/32 bit integers into
 +              // HMUL by a constant
 +
 +              // Arg[0] is already in AX as it's the only register we allow
 +              // and DX is the only output we care about (the high bits)
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[1])
 +
 +              // IMULB puts the high portion in AH instead of DL,
 +              // so move it to DL for consistency
 +              if v.Type.Size() == 1 {
 +                      m := Prog(x86.AMOVB)
 +                      m.From.Type = obj.TYPE_REG
 +                      m.From.Reg = x86.REG_AH
 +                      m.To.Type = obj.TYPE_REG
 +                      m.To.Reg = x86.REG_DX
 +              }
 +
 +      case ssa.OpAMD64SHLQ, ssa.OpAMD64SHLL, ssa.OpAMD64SHLW, ssa.OpAMD64SHLB,
 +              ssa.OpAMD64SHRQ, ssa.OpAMD64SHRL, ssa.OpAMD64SHRW, ssa.OpAMD64SHRB,
 +              ssa.OpAMD64SARQ, ssa.OpAMD64SARL, ssa.OpAMD64SARW, ssa.OpAMD64SARB:
 +              x := regnum(v.Args[0])
 +              r := regnum(v)
 +              if x != r {
 +                      if r == x86.REG_CX {
 +                              v.Fatalf("can't implement %s, target and shift both in CX", v.LongString())
 +                      }
 +                      p := Prog(regMoveAMD64(v.Type.Size()))
 +                      p.From.Type = obj.TYPE_REG
 +                      p.From.Reg = x
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +              }
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[1]) // should be CX
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = r
 +      case ssa.OpAMD64ADDQconst, ssa.OpAMD64ADDLconst, ssa.OpAMD64ADDWconst:
 +              // TODO: use addq instead of leaq if target is in the right register.
 +              var asm int
 +              switch v.Op {
 +              case ssa.OpAMD64ADDQconst:
 +                      asm = x86.ALEAQ
 +              case ssa.OpAMD64ADDLconst:
 +                      asm = x86.ALEAL
 +              case ssa.OpAMD64ADDWconst:
 +                      asm = x86.ALEAW
 +              }
 +              p := Prog(asm)
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              p.From.Offset = v.AuxInt
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64MULQconst, ssa.OpAMD64MULLconst, ssa.OpAMD64MULWconst, ssa.OpAMD64MULBconst:
 +              r := regnum(v)
 +              x := regnum(v.Args[0])
 +              if r != x {
 +                      p := Prog(regMoveAMD64(v.Type.Size()))
 +                      p.From.Type = obj.TYPE_REG
 +                      p.From.Reg = x
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +              }
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_CONST
 +              p.From.Offset = v.AuxInt
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = r
 +              // TODO: Teach doasm to compile the three-address multiply imul $c, r1, r2
 +              // instead of using the MOVQ above.
 +              //p.From3 = new(obj.Addr)
 +              //p.From3.Type = obj.TYPE_REG
 +              //p.From3.Reg = regnum(v.Args[0])
 +      case ssa.OpAMD64ADDBconst,
 +              ssa.OpAMD64ANDQconst, ssa.OpAMD64ANDLconst, ssa.OpAMD64ANDWconst, ssa.OpAMD64ANDBconst,
 +              ssa.OpAMD64ORQconst, ssa.OpAMD64ORLconst, ssa.OpAMD64ORWconst, ssa.OpAMD64ORBconst,
 +              ssa.OpAMD64XORQconst, ssa.OpAMD64XORLconst, ssa.OpAMD64XORWconst, ssa.OpAMD64XORBconst,
 +              ssa.OpAMD64SUBQconst, ssa.OpAMD64SUBLconst, ssa.OpAMD64SUBWconst, ssa.OpAMD64SUBBconst,
 +              ssa.OpAMD64SHLQconst, ssa.OpAMD64SHLLconst, ssa.OpAMD64SHLWconst, ssa.OpAMD64SHLBconst,
 +              ssa.OpAMD64SHRQconst, ssa.OpAMD64SHRLconst, ssa.OpAMD64SHRWconst, ssa.OpAMD64SHRBconst,
 +              ssa.OpAMD64SARQconst, ssa.OpAMD64SARLconst, ssa.OpAMD64SARWconst, ssa.OpAMD64SARBconst,
 +              ssa.OpAMD64ROLQconst, ssa.OpAMD64ROLLconst, ssa.OpAMD64ROLWconst, ssa.OpAMD64ROLBconst:
 +              // This code compensates for the fact that the register allocator
 +              // doesn't understand 2-address instructions yet.  TODO: fix that.
 +              x := regnum(v.Args[0])
 +              r := regnum(v)
 +              if x != r {
 +                      p := Prog(regMoveAMD64(v.Type.Size()))
 +                      p.From.Type = obj.TYPE_REG
 +                      p.From.Reg = x
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +              }
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_CONST
 +              p.From.Offset = v.AuxInt
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = r
 +      case ssa.OpAMD64SBBQcarrymask, ssa.OpAMD64SBBLcarrymask:
 +              r := regnum(v)
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = r
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = r
 +      case ssa.OpAMD64LEAQ1, ssa.OpAMD64LEAQ2, ssa.OpAMD64LEAQ4, ssa.OpAMD64LEAQ8:
 +              p := Prog(x86.ALEAQ)
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              switch v.Op {
 +              case ssa.OpAMD64LEAQ1:
 +                      p.From.Scale = 1
 +              case ssa.OpAMD64LEAQ2:
 +                      p.From.Scale = 2
 +              case ssa.OpAMD64LEAQ4:
 +                      p.From.Scale = 4
 +              case ssa.OpAMD64LEAQ8:
 +                      p.From.Scale = 8
 +              }
 +              p.From.Index = regnum(v.Args[1])
 +              addAux(&p.From, v)
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64LEAQ:
 +              p := Prog(x86.ALEAQ)
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              addAux(&p.From, v)
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64CMPQ, ssa.OpAMD64CMPL, ssa.OpAMD64CMPW, ssa.OpAMD64CMPB,
 +              ssa.OpAMD64TESTQ, ssa.OpAMD64TESTL, ssa.OpAMD64TESTW, ssa.OpAMD64TESTB:
 +              opregreg(v.Op.Asm(), regnum(v.Args[1]), regnum(v.Args[0]))
 +      case ssa.OpAMD64UCOMISS, ssa.OpAMD64UCOMISD:
 +              // Go assembler has swapped operands for UCOMISx relative to CMP,
 +              // must account for that right here.
 +              opregreg(v.Op.Asm(), regnum(v.Args[0]), regnum(v.Args[1]))
 +      case ssa.OpAMD64CMPQconst, ssa.OpAMD64CMPLconst, ssa.OpAMD64CMPWconst, ssa.OpAMD64CMPBconst,
 +              ssa.OpAMD64TESTQconst, ssa.OpAMD64TESTLconst, ssa.OpAMD64TESTWconst, ssa.OpAMD64TESTBconst:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[0])
 +              p.To.Type = obj.TYPE_CONST
 +              p.To.Offset = v.AuxInt
 +      case ssa.OpAMD64MOVBconst, ssa.OpAMD64MOVWconst, ssa.OpAMD64MOVLconst, ssa.OpAMD64MOVQconst:
 +              x := regnum(v)
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_CONST
 +              var i int64
 +              switch v.Op {
 +              case ssa.OpAMD64MOVBconst:
 +                      i = int64(int8(v.AuxInt))
 +              case ssa.OpAMD64MOVWconst:
 +                      i = int64(int16(v.AuxInt))
 +              case ssa.OpAMD64MOVLconst:
 +                      i = int64(int32(v.AuxInt))
 +              case ssa.OpAMD64MOVQconst:
 +                      i = v.AuxInt
 +              }
 +              p.From.Offset = i
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = x
 +      case ssa.OpAMD64MOVSSconst, ssa.OpAMD64MOVSDconst:
 +              x := regnum(v)
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_FCONST
 +              p.From.Val = math.Float64frombits(uint64(v.AuxInt))
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = x
 +      case ssa.OpAMD64MOVQload, ssa.OpAMD64MOVSSload, ssa.OpAMD64MOVSDload, ssa.OpAMD64MOVLload, ssa.OpAMD64MOVWload, ssa.OpAMD64MOVBload, ssa.OpAMD64MOVBQSXload, ssa.OpAMD64MOVBQZXload, ssa.OpAMD64MOVOload:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              addAux(&p.From, v)
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64MOVQloadidx8, ssa.OpAMD64MOVSDloadidx8:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              addAux(&p.From, v)
 +              p.From.Scale = 8
 +              p.From.Index = regnum(v.Args[1])
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64MOVSSloadidx4:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Reg = regnum(v.Args[0])
 +              addAux(&p.From, v)
 +              p.From.Scale = 4
 +              p.From.Index = regnum(v.Args[1])
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpAMD64MOVQstore, ssa.OpAMD64MOVSSstore, ssa.OpAMD64MOVSDstore, ssa.OpAMD64MOVLstore, ssa.OpAMD64MOVWstore, ssa.OpAMD64MOVBstore, ssa.OpAMD64MOVOstore:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[1])
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Reg = regnum(v.Args[0])
 +              addAux(&p.To, v)
 +      case ssa.OpAMD64MOVQstoreidx8, ssa.OpAMD64MOVSDstoreidx8:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[2])
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Reg = regnum(v.Args[0])
 +              p.To.Scale = 8
 +              p.To.Index = regnum(v.Args[1])
 +              addAux(&p.To, v)
 +      case ssa.OpAMD64MOVSSstoreidx4:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[2])
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Reg = regnum(v.Args[0])
 +              p.To.Scale = 4
 +              p.To.Index = regnum(v.Args[1])
 +              addAux(&p.To, v)
 +      case ssa.OpAMD64MOVQstoreconst, ssa.OpAMD64MOVLstoreconst, ssa.OpAMD64MOVWstoreconst, ssa.OpAMD64MOVBstoreconst:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_CONST
 +              sc := ssa.StoreConst(v.AuxInt)
 +              i := sc.Val()
 +              switch v.Op {
 +              case ssa.OpAMD64MOVBstoreconst:
 +                      i = int64(int8(i))
 +              case ssa.OpAMD64MOVWstoreconst:
 +                      i = int64(int16(i))
 +              case ssa.OpAMD64MOVLstoreconst:
 +                      i = int64(int32(i))
 +              case ssa.OpAMD64MOVQstoreconst:
 +              }
 +              p.From.Offset = i
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Reg = regnum(v.Args[0])
 +              addAux2(&p.To, v, sc.Off())
 +      case ssa.OpAMD64MOVLQSX, ssa.OpAMD64MOVWQSX, ssa.OpAMD64MOVBQSX, ssa.OpAMD64MOVLQZX, ssa.OpAMD64MOVWQZX, ssa.OpAMD64MOVBQZX,
 +              ssa.OpAMD64CVTSL2SS, ssa.OpAMD64CVTSL2SD, ssa.OpAMD64CVTSQ2SS, ssa.OpAMD64CVTSQ2SD,
 +              ssa.OpAMD64CVTTSS2SL, ssa.OpAMD64CVTTSD2SL, ssa.OpAMD64CVTTSS2SQ, ssa.OpAMD64CVTTSD2SQ,
 +              ssa.OpAMD64CVTSS2SD, ssa.OpAMD64CVTSD2SS:
 +              opregreg(v.Op.Asm(), regnum(v), regnum(v.Args[0]))
 +      case ssa.OpAMD64DUFFZERO:
 +              p := Prog(obj.ADUFFZERO)
 +              p.To.Type = obj.TYPE_ADDR
 +              p.To.Sym = Linksym(Pkglookup("duffzero", Runtimepkg))
 +              p.To.Offset = v.AuxInt
 +      case ssa.OpAMD64MOVOconst:
 +              if v.AuxInt != 0 {
 +                      v.Unimplementedf("MOVOconst can only do constant=0")
 +              }
 +              r := regnum(v)
 +              opregreg(x86.AXORPS, r, r)
 +      case ssa.OpAMD64DUFFCOPY:
 +              p := Prog(obj.ADUFFCOPY)
 +              p.To.Type = obj.TYPE_ADDR
 +              p.To.Sym = Linksym(Pkglookup("duffcopy", Runtimepkg))
 +              p.To.Offset = v.AuxInt
 +
 +      case ssa.OpCopy, ssa.OpAMD64MOVQconvert: // TODO: lower Copy to MOVQ earlier?
 +              if v.Type.IsMemory() {
 +                      return
 +              }
 +              x := regnum(v.Args[0])
 +              y := regnum(v)
 +              if x != y {
 +                      opregreg(regMoveByTypeAMD64(v.Type), y, x)
 +              }
 +      case ssa.OpLoadReg:
 +              if v.Type.IsFlags() {
 +                      v.Unimplementedf("load flags not implemented: %v", v.LongString())
 +                      return
 +              }
 +              p := Prog(movSizeByType(v.Type))
 +              n, off := autoVar(v.Args[0])
 +              p.From.Type = obj.TYPE_MEM
 +              p.From.Node = n
 +              p.From.Sym = Linksym(n.Sym)
 +              p.From.Offset = off
 +              if n.Class == PPARAM {
 +                      p.From.Name = obj.NAME_PARAM
 +                      p.From.Offset += n.Xoffset
 +              } else {
 +                      p.From.Name = obj.NAME_AUTO
 +              }
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +
 +      case ssa.OpStoreReg:
 +              if v.Type.IsFlags() {
 +                      v.Unimplementedf("store flags not implemented: %v", v.LongString())
 +                      return
 +              }
 +              p := Prog(movSizeByType(v.Type))
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[0])
 +              n, off := autoVar(v)
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Node = n
 +              p.To.Sym = Linksym(n.Sym)
 +              p.To.Offset = off
 +              if n.Class == PPARAM {
 +                      p.To.Name = obj.NAME_PARAM
 +                      p.To.Offset += n.Xoffset
 +              } else {
 +                      p.To.Name = obj.NAME_AUTO
 +              }
 +      case ssa.OpPhi:
 +              // just check to make sure regalloc and stackalloc did it right
 +              if v.Type.IsMemory() {
 +                      return
 +              }
 +              f := v.Block.Func
 +              loc := f.RegAlloc[v.ID]
 +              for _, a := range v.Args {
 +                      if aloc := f.RegAlloc[a.ID]; aloc != loc { // TODO: .Equal() instead?
 +                              v.Fatalf("phi arg at different location than phi: %v @ %v, but arg %v @ %v\n%s\n", v, loc, a, aloc, v.Block.Func)
 +                      }
 +              }
 +      case ssa.OpConst8, ssa.OpConst16, ssa.OpConst32, ssa.OpConst64, ssa.OpConstString, ssa.OpConstNil, ssa.OpConstBool,
 +              ssa.OpConst32F, ssa.OpConst64F:
 +              if v.Block.Func.RegAlloc[v.ID] != nil {
 +                      v.Fatalf("const value %v shouldn't have a location", v)
 +              }
 +
 +      case ssa.OpInitMem:
 +              // memory arg needs no code
 +      case ssa.OpArg:
 +              // input args need no code
 +      case ssa.OpAMD64LoweredGetClosurePtr:
 +              // Output is hardwired to DX only,
 +              // and DX contains the closure pointer on
 +              // closure entry, and this "instruction"
 +              // is scheduled to the very beginning
 +              // of the entry block.
 +      case ssa.OpAMD64LoweredGetG:
 +              r := regnum(v)
 +              // See the comments in cmd/internal/obj/x86/obj6.go
 +              // near CanUse1InsnTLS for a detailed explanation of these instructions.
 +              if x86.CanUse1InsnTLS(Ctxt) {
 +                      // MOVQ (TLS), r
 +                      p := Prog(x86.AMOVQ)
 +                      p.From.Type = obj.TYPE_MEM
 +                      p.From.Reg = x86.REG_TLS
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +              } else {
 +                      // MOVQ TLS, r
 +                      // MOVQ (r)(TLS*1), r
 +                      p := Prog(x86.AMOVQ)
 +                      p.From.Type = obj.TYPE_REG
 +                      p.From.Reg = x86.REG_TLS
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +                      q := Prog(x86.AMOVQ)
 +                      q.From.Type = obj.TYPE_MEM
 +                      q.From.Reg = r
 +                      q.From.Index = x86.REG_TLS
 +                      q.From.Scale = 1
 +                      q.To.Type = obj.TYPE_REG
 +                      q.To.Reg = r
 +              }
 +      case ssa.OpAMD64CALLstatic:
 +              p := Prog(obj.ACALL)
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Name = obj.NAME_EXTERN
 +              p.To.Sym = Linksym(v.Aux.(*Sym))
 +              if Maxarg < v.AuxInt {
 +                      Maxarg = v.AuxInt
 +              }
 +      case ssa.OpAMD64CALLclosure:
 +              p := Prog(obj.ACALL)
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v.Args[0])
 +              if Maxarg < v.AuxInt {
 +                      Maxarg = v.AuxInt
 +              }
 +      case ssa.OpAMD64CALLdefer:
 +              p := Prog(obj.ACALL)
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Name = obj.NAME_EXTERN
 +              p.To.Sym = Linksym(Deferproc.Sym)
 +              if Maxarg < v.AuxInt {
 +                      Maxarg = v.AuxInt
 +              }
 +              // defer returns in rax:
 +              // 0 if we should continue executing
 +              // 1 if we should jump to deferreturn call
 +              p = Prog(x86.ATESTL)
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = x86.REG_AX
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = x86.REG_AX
 +              p = Prog(x86.AJNE)
 +              p.To.Type = obj.TYPE_BRANCH
 +              s.deferBranches = append(s.deferBranches, p)
 +      case ssa.OpAMD64CALLgo:
 +              p := Prog(obj.ACALL)
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Name = obj.NAME_EXTERN
 +              p.To.Sym = Linksym(Newproc.Sym)
 +              if Maxarg < v.AuxInt {
 +                      Maxarg = v.AuxInt
 +              }
 +      case ssa.OpAMD64CALLinter:
 +              p := Prog(obj.ACALL)
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v.Args[0])
 +              if Maxarg < v.AuxInt {
 +                      Maxarg = v.AuxInt
 +              }
 +      case ssa.OpAMD64NEGQ, ssa.OpAMD64NEGL, ssa.OpAMD64NEGW, ssa.OpAMD64NEGB,
 +              ssa.OpAMD64NOTQ, ssa.OpAMD64NOTL, ssa.OpAMD64NOTW, ssa.OpAMD64NOTB:
 +              x := regnum(v.Args[0])
 +              r := regnum(v)
 +              if x != r {
 +                      p := Prog(regMoveAMD64(v.Type.Size()))
 +                      p.From.Type = obj.TYPE_REG
 +                      p.From.Reg = x
 +                      p.To.Type = obj.TYPE_REG
 +                      p.To.Reg = r
 +              }
 +              p := Prog(v.Op.Asm())
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = r
 +      case ssa.OpAMD64SQRTSD:
 +              p := Prog(v.Op.Asm())
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = regnum(v.Args[0])
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +      case ssa.OpSP, ssa.OpSB:
 +              // nothing to do
 +      case ssa.OpAMD64SETEQ, ssa.OpAMD64SETNE,
 +              ssa.OpAMD64SETL, ssa.OpAMD64SETLE,
 +              ssa.OpAMD64SETG, ssa.OpAMD64SETGE,
 +              ssa.OpAMD64SETGF, ssa.OpAMD64SETGEF,
 +              ssa.OpAMD64SETB, ssa.OpAMD64SETBE,
 +              ssa.OpAMD64SETORD, ssa.OpAMD64SETNAN,
 +              ssa.OpAMD64SETA, ssa.OpAMD64SETAE:
 +              p := Prog(v.Op.Asm())
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +
 +      case ssa.OpAMD64SETNEF:
 +              p := Prog(v.Op.Asm())
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +              q := Prog(x86.ASETPS)
 +              q.To.Type = obj.TYPE_REG
 +              q.To.Reg = x86.REG_AX
 +              // TODO AORQ copied from old code generator, why not AORB?
 +              opregreg(x86.AORQ, regnum(v), x86.REG_AX)
 +
 +      case ssa.OpAMD64SETEQF:
 +              p := Prog(v.Op.Asm())
 +              p.To.Type = obj.TYPE_REG
 +              p.To.Reg = regnum(v)
 +              q := Prog(x86.ASETPC)
 +              q.To.Type = obj.TYPE_REG
 +              q.To.Reg = x86.REG_AX
 +              // TODO AANDQ copied from old code generator, why not AANDB?
 +              opregreg(x86.AANDQ, regnum(v), x86.REG_AX)
 +
 +      case ssa.OpAMD64InvertFlags:
 +              v.Fatalf("InvertFlags should never make it to codegen %v", v)
 +      case ssa.OpAMD64REPSTOSQ:
 +              Prog(x86.AREP)
 +              Prog(x86.ASTOSQ)
 +      case ssa.OpAMD64REPMOVSQ:
 +              Prog(x86.AREP)
 +              Prog(x86.AMOVSQ)
 +      case ssa.OpVarDef:
 +              Gvardef(v.Aux.(*Node))
 +      case ssa.OpVarKill:
 +              gvarkill(v.Aux.(*Node))
 +      case ssa.OpAMD64LoweredNilCheck:
 +              // Optimization - if the subsequent block has a load or store
 +              // at the same address, we don't need to issue this instruction.
 +              for _, w := range v.Block.Succs[0].Values {
 +                      if len(w.Args) == 0 || !w.Args[len(w.Args)-1].Type.IsMemory() {
 +                              // w doesn't use a store - can't be a memory op.
 +                              continue
 +                      }
 +                      if w.Args[len(w.Args)-1] != v.Args[1] {
 +                              v.Fatalf("wrong store after nilcheck v=%s w=%s", v, w)
 +                      }
 +                      switch w.Op {
 +                      case ssa.OpAMD64MOVQload, ssa.OpAMD64MOVLload, ssa.OpAMD64MOVWload, ssa.OpAMD64MOVBload,
 +                              ssa.OpAMD64MOVQstore, ssa.OpAMD64MOVLstore, ssa.OpAMD64MOVWstore, ssa.OpAMD64MOVBstore:
 +                              if w.Args[0] == v.Args[0] && w.Aux == nil && w.AuxInt >= 0 && w.AuxInt < minZeroPage {
 +                                      return
 +                              }
 +                      case ssa.OpAMD64MOVQstoreconst, ssa.OpAMD64MOVLstoreconst, ssa.OpAMD64MOVWstoreconst, ssa.OpAMD64MOVBstoreconst:
 +                              off := ssa.StoreConst(v.AuxInt).Off()
 +                              if w.Args[0] == v.Args[0] && w.Aux == nil && off >= 0 && off < minZeroPage {
 +                                      return
 +                              }
 +                      }
 +                      if w.Type.IsMemory() {
 +                              // We can't delay the nil check past the next store.
 +                              break
 +                      }
 +              }
 +              // Issue a load which will fault if the input is nil.
 +              // TODO: We currently use the 2-byte instruction TESTB AX, (reg).
 +              // Should we use the 3-byte TESTB $0, (reg) instead?  It is larger
 +              // but it doesn't have false dependency on AX.
 +              // Or maybe allocate an output register and use MOVL (reg),reg2 ?
 +              // That trades clobbering flags for clobbering a register.
 +              p := Prog(x86.ATESTB)
 +              p.From.Type = obj.TYPE_REG
 +              p.From.Reg = x86.REG_AX
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Reg = regnum(v.Args[0])
 +              addAux(&p.To, v)
 +              if Debug_checknil != 0 && v.Line > 1 { // v.Line==1 in generated wrappers
 +                      Warnl(int(v.Line), "generated nil check")
 +              }
 +      default:
 +              v.Unimplementedf("genValue not implemented: %s", v.LongString())
 +      }
 +}
 +
 +// movSizeByType returns the MOV instruction of the given type.
 +func movSizeByType(t ssa.Type) (asm int) {
 +      // For x86, there's no difference between reg move opcodes
 +      // and memory move opcodes.
 +      asm = regMoveByTypeAMD64(t)
 +      return
 +}
 +
 +// movZero generates a register indirect move with a 0 immediate and keeps track of bytes left and next offset
 +func movZero(as int, width int64, nbytes int64, offset int64, regnum int16) (nleft int64, noff int64) {
 +      p := Prog(as)
 +      // TODO: use zero register on archs that support it.
 +      p.From.Type = obj.TYPE_CONST
 +      p.From.Offset = 0
 +      p.To.Type = obj.TYPE_MEM
 +      p.To.Reg = regnum
 +      p.To.Offset = offset
 +      offset += width
 +      nleft = nbytes - width
 +      return nleft, offset
 +}
 +
 +var blockJump = [...]struct {
 +      asm, invasm int
 +}{
 +      ssa.BlockAMD64EQ:  {x86.AJEQ, x86.AJNE},
 +      ssa.BlockAMD64NE:  {x86.AJNE, x86.AJEQ},
 +      ssa.BlockAMD64LT:  {x86.AJLT, x86.AJGE},
 +      ssa.BlockAMD64GE:  {x86.AJGE, x86.AJLT},
 +      ssa.BlockAMD64LE:  {x86.AJLE, x86.AJGT},
 +      ssa.BlockAMD64GT:  {x86.AJGT, x86.AJLE},
 +      ssa.BlockAMD64ULT: {x86.AJCS, x86.AJCC},
 +      ssa.BlockAMD64UGE: {x86.AJCC, x86.AJCS},
 +      ssa.BlockAMD64UGT: {x86.AJHI, x86.AJLS},
 +      ssa.BlockAMD64ULE: {x86.AJLS, x86.AJHI},
 +      ssa.BlockAMD64ORD: {x86.AJPC, x86.AJPS},
 +      ssa.BlockAMD64NAN: {x86.AJPS, x86.AJPC},
 +}
 +
 +type floatingEQNEJump struct {
 +      jump, index int
 +}
 +
 +var eqfJumps = [2][2]floatingEQNEJump{
 +      {{x86.AJNE, 1}, {x86.AJPS, 1}}, // next == b.Succs[0]
 +      {{x86.AJNE, 1}, {x86.AJPC, 0}}, // next == b.Succs[1]
 +}
 +var nefJumps = [2][2]floatingEQNEJump{
 +      {{x86.AJNE, 0}, {x86.AJPC, 1}}, // next == b.Succs[0]
 +      {{x86.AJNE, 0}, {x86.AJPS, 0}}, // next == b.Succs[1]
 +}
 +
 +func oneFPJump(b *ssa.Block, jumps *floatingEQNEJump, likely ssa.BranchPrediction, branches []branch) []branch {
 +      p := Prog(jumps.jump)
 +      p.To.Type = obj.TYPE_BRANCH
 +      to := jumps.index
 +      branches = append(branches, branch{p, b.Succs[to]})
 +      if to == 1 {
 +              likely = -likely
 +      }
 +      // liblink reorders the instruction stream as it sees fit.
 +      // Pass along what we know so liblink can make use of it.
 +      // TODO: Once we've fully switched to SSA,
 +      // make liblink leave our output alone.
 +      switch likely {
 +      case ssa.BranchUnlikely:
 +              p.From.Type = obj.TYPE_CONST
 +              p.From.Offset = 0
 +      case ssa.BranchLikely:
 +              p.From.Type = obj.TYPE_CONST
 +              p.From.Offset = 1
 +      }
 +      return branches
 +}
 +
 +func genFPJump(s *genState, b, next *ssa.Block, jumps *[2][2]floatingEQNEJump) {
 +      likely := b.Likely
 +      switch next {
 +      case b.Succs[0]:
 +              s.branches = oneFPJump(b, &jumps[0][0], likely, s.branches)
 +              s.branches = oneFPJump(b, &jumps[0][1], likely, s.branches)
 +      case b.Succs[1]:
 +              s.branches = oneFPJump(b, &jumps[1][0], likely, s.branches)
 +              s.branches = oneFPJump(b, &jumps[1][1], likely, s.branches)
 +      default:
 +              s.branches = oneFPJump(b, &jumps[1][0], likely, s.branches)
 +              s.branches = oneFPJump(b, &jumps[1][1], likely, s.branches)
 +              q := Prog(obj.AJMP)
 +              q.To.Type = obj.TYPE_BRANCH
 +              s.branches = append(s.branches, branch{q, b.Succs[1]})
 +      }
 +}
 +
 +func (s *genState) genBlock(b, next *ssa.Block) {
 +      lineno = b.Line
 +
 +      switch b.Kind {
 +      case ssa.BlockPlain, ssa.BlockCall, ssa.BlockCheck:
 +              if b.Succs[0] != next {
 +                      p := Prog(obj.AJMP)
 +                      p.To.Type = obj.TYPE_BRANCH
 +                      s.branches = append(s.branches, branch{p, b.Succs[0]})
 +              }
 +      case ssa.BlockExit:
 +              Prog(obj.AUNDEF) // tell plive.go that we never reach here
 +      case ssa.BlockRet:
 +              if hasdefer {
 +                      s.deferReturn()
 +              }
 +              Prog(obj.ARET)
 +      case ssa.BlockRetJmp:
 +              p := Prog(obj.AJMP)
 +              p.To.Type = obj.TYPE_MEM
 +              p.To.Name = obj.NAME_EXTERN
 +              p.To.Sym = Linksym(b.Aux.(*Sym))
 +
 +      case ssa.BlockAMD64EQF:
 +              genFPJump(s, b, next, &eqfJumps)
 +
 +      case ssa.BlockAMD64NEF:
 +              genFPJump(s, b, next, &nefJumps)
 +
 +      case ssa.BlockAMD64EQ, ssa.BlockAMD64NE,
 +              ssa.BlockAMD64LT, ssa.BlockAMD64GE,
 +              ssa.BlockAMD64LE, ssa.BlockAMD64GT,
 +              ssa.BlockAMD64ULT, ssa.BlockAMD64UGT,
 +              ssa.BlockAMD64ULE, ssa.BlockAMD64UGE:
 +              jmp := blockJump[b.Kind]
 +              likely := b.Likely
 +              var p *obj.Prog
 +              switch next {
 +              case b.Succs[0]:
 +                      p = Prog(jmp.invasm)
 +                      likely *= -1
 +                      p.To.Type = obj.TYPE_BRANCH
 +                      s.branches = append(s.branches, branch{p, b.Succs[1]})
 +              case b.Succs[1]:
 +                      p = Prog(jmp.asm)
 +                      p.To.Type = obj.TYPE_BRANCH
 +                      s.branches = append(s.branches, branch{p, b.Succs[0]})
 +              default:
 +                      p = Prog(jmp.asm)
 +                      p.To.Type = obj.TYPE_BRANCH
 +                      s.branches = append(s.branches, branch{p, b.Succs[0]})
 +                      q := Prog(obj.AJMP)
 +                      q.To.Type = obj.TYPE_BRANCH
 +                      s.branches = append(s.branches, branch{q, b.Succs[1]})
 +              }
 +
 +              // liblink reorders the instruction stream as it sees fit.
 +              // Pass along what we know so liblink can make use of it.
 +              // TODO: Once we've fully switched to SSA,
 +              // make liblink leave our output alone.
 +              switch likely {
 +              case ssa.BranchUnlikely:
 +                      p.From.Type = obj.TYPE_CONST
 +                      p.From.Offset = 0
 +              case ssa.BranchLikely:
 +                      p.From.Type = obj.TYPE_CONST
 +                      p.From.Offset = 1
 +              }
 +
 +      default:
 +              b.Unimplementedf("branch not implemented: %s. Control: %s", b.LongString(), b.Control.LongString())
 +      }
 +}
 +
 +func (s *genState) deferReturn() {
 +      // Deferred calls will appear to be returning to
 +      // the CALL deferreturn(SB) that we are about to emit.
 +      // However, the stack trace code will show the line
 +      // of the instruction byte before the return PC.
 +      // To avoid that being an unrelated instruction,
 +      // insert an actual hardware NOP that will have the right line number.
 +      // This is different from obj.ANOP, which is a virtual no-op
 +      // that doesn't make it into the instruction stream.
 +      s.deferTarget = Pc
 +      Thearch.Ginsnop()
 +      p := Prog(obj.ACALL)
 +      p.To.Type = obj.TYPE_MEM
 +      p.To.Name = obj.NAME_EXTERN
 +      p.To.Sym = Linksym(Deferreturn.Sym)
 +}
 +
 +// addAux adds the offset in the aux fields (AuxInt and Aux) of v to a.
 +func addAux(a *obj.Addr, v *ssa.Value) {
 +      addAux2(a, v, v.AuxInt)
 +}
 +func addAux2(a *obj.Addr, v *ssa.Value, offset int64) {
 +      if a.Type != obj.TYPE_MEM {
 +              v.Fatalf("bad addAux addr %s", a)
 +      }
 +      // add integer offset
 +      a.Offset += offset
 +
 +      // If no additional symbol offset, we're done.
 +      if v.Aux == nil {
 +              return
 +      }
 +      // Add symbol's offset from its base register.
 +      switch sym := v.Aux.(type) {
 +      case *ssa.ExternSymbol:
 +              a.Name = obj.NAME_EXTERN
 +              a.Sym = Linksym(sym.Sym.(*Sym))
 +      case *ssa.ArgSymbol:
 +              n := sym.Node.(*Node)
 +              a.Name = obj.NAME_PARAM
 +              a.Node = n
 +              a.Sym = Linksym(n.Orig.Sym)
 +              a.Offset += n.Xoffset // TODO: why do I have to add this here?  I don't for auto variables.
 +      case *ssa.AutoSymbol:
 +              n := sym.Node.(*Node)
 +              a.Name = obj.NAME_AUTO
 +              a.Node = n
 +              a.Sym = Linksym(n.Sym)
 +      default:
 +              v.Fatalf("aux in %s not implemented %#v", v, v.Aux)
 +      }
 +}
 +
 +// extendIndex extends v to a full int width.
 +func (s *state) extendIndex(v *ssa.Value) *ssa.Value {
 +      size := v.Type.Size()
 +      if size == s.config.IntSize {
 +              return v
 +      }
 +      if size > s.config.IntSize {
 +              // TODO: truncate 64-bit indexes on 32-bit pointer archs.  We'd need to test
 +              // the high word and branch to out-of-bounds failure if it is not 0.
 +              s.Unimplementedf("64->32 index truncation not implemented")
 +              return v
 +      }
 +
 +      // Extend value to the required size
 +      var op ssa.Op
 +      if v.Type.IsSigned() {
 +              switch 10*size + s.config.IntSize {
 +              case 14:
 +                      op = ssa.OpSignExt8to32
 +              case 18:
 +                      op = ssa.OpSignExt8to64
 +              case 24:
 +                      op = ssa.OpSignExt16to32
 +              case 28:
 +                      op = ssa.OpSignExt16to64
 +              case 48:
 +                      op = ssa.OpSignExt32to64
 +              default:
 +                      s.Fatalf("bad signed index extension %s", v.Type)
 +              }
 +      } else {
 +              switch 10*size + s.config.IntSize {
 +              case 14:
 +                      op = ssa.OpZeroExt8to32
 +              case 18:
 +                      op = ssa.OpZeroExt8to64
 +              case 24:
 +                      op = ssa.OpZeroExt16to32
 +              case 28:
 +                      op = ssa.OpZeroExt16to64
 +              case 48:
 +                      op = ssa.OpZeroExt32to64
 +              default:
 +                      s.Fatalf("bad unsigned index extension %s", v.Type)
 +              }
 +      }
 +      return s.newValue1(op, Types[TINT], v)
 +}
 +
 +// ssaRegToReg maps ssa register numbers to obj register numbers.
 +var ssaRegToReg = [...]int16{
 +      x86.REG_AX,
 +      x86.REG_CX,
 +      x86.REG_DX,
 +      x86.REG_BX,
 +      x86.REG_SP,
 +      x86.REG_BP,
 +      x86.REG_SI,
 +      x86.REG_DI,
 +      x86.REG_R8,
 +      x86.REG_R9,
 +      x86.REG_R10,
 +      x86.REG_R11,
 +      x86.REG_R12,
 +      x86.REG_R13,
 +      x86.REG_R14,
 +      x86.REG_R15,
 +      x86.REG_X0,
 +      x86.REG_X1,
 +      x86.REG_X2,
 +      x86.REG_X3,
 +      x86.REG_X4,
 +      x86.REG_X5,
 +      x86.REG_X6,
 +      x86.REG_X7,
 +      x86.REG_X8,
 +      x86.REG_X9,
 +      x86.REG_X10,
 +      x86.REG_X11,
 +      x86.REG_X12,
 +      x86.REG_X13,
 +      x86.REG_X14,
 +      x86.REG_X15,
 +      0, // SB isn't a real register.  We fill an Addr.Reg field with 0 in this case.
 +      // TODO: arch-dependent
 +}
 +
 +// regMoveAMD64 returns the register->register move opcode for the given width.
 +// TODO: generalize for all architectures?
 +func regMoveAMD64(width int64) int {
 +      switch width {
 +      case 1:
 +              return x86.AMOVB
 +      case 2:
 +              return x86.AMOVW
 +      case 4:
 +              return x86.AMOVL
 +      case 8:
 +              return x86.AMOVQ
 +      default:
 +              panic("bad int register width")
 +      }
 +}
 +
 +func regMoveByTypeAMD64(t ssa.Type) int {
 +      width := t.Size()
 +      if t.IsFloat() {
 +              switch width {
 +              case 4:
 +                      return x86.AMOVSS
 +              case 8:
 +                      return x86.AMOVSD
 +              default:
 +                      panic("bad float register width")
 +              }
 +      } else {
 +              switch width {
 +              case 1:
 +                      return x86.AMOVB
 +              case 2:
 +                      return x86.AMOVW
 +              case 4:
 +                      return x86.AMOVL
 +              case 8:
 +                      return x86.AMOVQ
 +              default:
 +                      panic("bad int register width")
 +              }
 +      }
 +
 +      panic("bad register type")
 +}
 +
 +// regnum returns the register (in cmd/internal/obj numbering) to
 +// which v has been allocated.  Panics if v is not assigned to a
 +// register.
 +// TODO: Make this panic again once it stops happening routinely.
 +func regnum(v *ssa.Value) int16 {
 +      reg := v.Block.Func.RegAlloc[v.ID]
 +      if reg == nil {
 +              v.Unimplementedf("nil regnum for value: %s\n%s\n", v.LongString(), v.Block.Func)
 +              return 0
 +      }
 +      return ssaRegToReg[reg.(*ssa.Register).Num]
 +}
 +
 +// autoVar returns a *Node and int64 representing the auto variable and offset within it
 +// where v should be spilled.
 +func autoVar(v *ssa.Value) (*Node, int64) {
 +      loc := v.Block.Func.RegAlloc[v.ID].(ssa.LocalSlot)
 +      return loc.N.(*Node), loc.Off
 +}
 +
 +// ssaExport exports a bunch of compiler services for the ssa backend.
 +type ssaExport struct {
 +      log           bool
 +      unimplemented bool
 +      mustImplement bool
 +}
 +
 +func (s *ssaExport) TypeBool() ssa.Type    { return Types[TBOOL] }
 +func (s *ssaExport) TypeInt8() ssa.Type    { return Types[TINT8] }
 +func (s *ssaExport) TypeInt16() ssa.Type   { return Types[TINT16] }
 +func (s *ssaExport) TypeInt32() ssa.Type   { return Types[TINT32] }
 +func (s *ssaExport) TypeInt64() ssa.Type   { return Types[TINT64] }
 +func (s *ssaExport) TypeUInt8() ssa.Type   { return Types[TUINT8] }
 +func (s *ssaExport) TypeUInt16() ssa.Type  { return Types[TUINT16] }
 +func (s *ssaExport) TypeUInt32() ssa.Type  { return Types[TUINT32] }
 +func (s *ssaExport) TypeUInt64() ssa.Type  { return Types[TUINT64] }
 +func (s *ssaExport) TypeFloat32() ssa.Type { return Types[TFLOAT32] }
 +func (s *ssaExport) TypeFloat64() ssa.Type { return Types[TFLOAT64] }
 +func (s *ssaExport) TypeInt() ssa.Type     { return Types[TINT] }
 +func (s *ssaExport) TypeUintptr() ssa.Type { return Types[TUINTPTR] }
 +func (s *ssaExport) TypeString() ssa.Type  { return Types[TSTRING] }
 +func (s *ssaExport) TypeBytePtr() ssa.Type { return Ptrto(Types[TUINT8]) }
 +
 +// StringData returns a symbol (a *Sym wrapped in an interface) which
 +// is the data component of a global string constant containing s.
 +func (*ssaExport) StringData(s string) interface{} {
 +      // TODO: is idealstring correct?  It might not matter...
 +      _, data := stringsym(s)
 +      return &ssa.ExternSymbol{Typ: idealstring, Sym: data}
 +}
 +
 +func (e *ssaExport) Auto(t ssa.Type) ssa.GCNode {
 +      n := temp(t.(*Type))   // Note: adds new auto to Curfn.Func.Dcl list
 +      e.mustImplement = true // This modifies the input to SSA, so we want to make sure we succeed from here!
 +      return n
 +}
 +
 +func (e *ssaExport) CanSSA(t ssa.Type) bool {
 +      return canSSAType(t.(*Type))
 +}
 +
 +// Log logs a message from the compiler.
 +func (e *ssaExport) Logf(msg string, args ...interface{}) {
 +      // If e was marked as unimplemented, anything could happen. Ignore.
 +      if e.log && !e.unimplemented {
 +              fmt.Printf(msg, args...)
 +      }
 +}
 +
 +// Fatal reports a compiler error and exits.
 +func (e *ssaExport) Fatalf(msg string, args ...interface{}) {
 +      // If e was marked as unimplemented, anything could happen. Ignore.
 +      if !e.unimplemented {
 +              Fatalf(msg, args...)
 +      }
 +}
 +
 +// Unimplemented reports that the function cannot be compiled.
 +// It will be removed once SSA work is complete.
 +func (e *ssaExport) Unimplementedf(msg string, args ...interface{}) {
 +      if e.mustImplement {
 +              Fatalf(msg, args...)
 +      }
 +      const alwaysLog = false // enable to calculate top unimplemented features
 +      if !e.unimplemented && (e.log || alwaysLog) {
 +              // first implementation failure, print explanation
 +              fmt.Printf("SSA unimplemented: "+msg+"\n", args...)
 +      }
 +      e.unimplemented = true
 +}
 +
 +// Warnl reports a "warning", which is usually flag-triggered
 +// logging output for the benefit of tests.
 +func (e *ssaExport) Warnl(line int, fmt_ string, args ...interface{}) {
 +      Warnl(line, fmt_, args...)
 +}
 +
 +func (e *ssaExport) Debug_checknil() bool {
 +      return Debug_checknil != 0
 +}
 +
 +func (n *Node) Typ() ssa.Type {
 +      return n.Type
 +}

diff --cc src/cmd/compile/internal/gc/syntax.go
Simple merge

diff --cc src/cmd/compile/internal/gc/type.go
index 483ebd96ea4aeea63d25e707f9e9745409fd38d2,0000000000000000000000000000000000000000..3f218ee3da2a864cf8d4e970868e40e658fc06c1
mode 100644,000000..100644
--- 1/src/cmd/compile/internal/gc/type.go
--- /dev/null
+++ b/src/cmd/compile/internal/gc/type.go
@@@ -1,145 -1,0 +1,145 @@@
-       return Econv(int(t.Etype), 0)
 +// Copyright 2015 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.
 +
 +// This file provides methods that let us export a Type as an ../ssa:Type.
 +// We don't export this package's Type directly because it would lead
 +// to an import cycle with this package and ../ssa.
 +// TODO: move Type to its own package, then we don't need to dance around import cycles.
 +
 +package gc
 +
 +import (
 +      "cmd/compile/internal/ssa"
 +)
 +
 +func (t *Type) Size() int64 {
 +      dowidth(t)
 +      return t.Width
 +}
 +
 +func (t *Type) Alignment() int64 {
 +      dowidth(t)
 +      return int64(t.Align)
 +}
 +
 +func (t *Type) SimpleString() string {
++      return Econv(t.Etype)
 +}
 +
 +func (t *Type) Equal(u ssa.Type) bool {
 +      x, ok := u.(*Type)
 +      if !ok {
 +              return false
 +      }
 +      return Eqtype(t, x)
 +}
 +
 +func (t *Type) IsBoolean() bool {
 +      return t.Etype == TBOOL
 +}
 +
 +func (t *Type) IsInteger() bool {
 +      switch t.Etype {
 +      case TINT8, TUINT8, TINT16, TUINT16, TINT32, TUINT32, TINT64, TUINT64, TINT, TUINT, TUINTPTR:
 +              return true
 +      }
 +      return false
 +}
 +
 +func (t *Type) IsSigned() bool {
 +      switch t.Etype {
 +      case TINT8, TINT16, TINT32, TINT64, TINT:
 +              return true
 +      }
 +      return false
 +}
 +
 +func (t *Type) IsFloat() bool {
 +      return t.Etype == TFLOAT32 || t.Etype == TFLOAT64
 +}
 +
 +func (t *Type) IsComplex() bool {
 +      return t.Etype == TCOMPLEX64 || t.Etype == TCOMPLEX128
 +}
 +
 +func (t *Type) IsPtr() bool {
 +      return t.Etype == TPTR32 || t.Etype == TPTR64 || t.Etype == TUNSAFEPTR ||
 +              t.Etype == TMAP || t.Etype == TCHAN || t.Etype == TFUNC
 +}
 +
 +func (t *Type) IsString() bool {
 +      return t.Etype == TSTRING
 +}
 +
 +func (t *Type) IsMap() bool {
 +      return t.Etype == TMAP
 +}
 +
 +func (t *Type) IsChan() bool {
 +      return t.Etype == TCHAN
 +}
 +
 +func (t *Type) IsSlice() bool {
 +      return t.Etype == TARRAY && t.Bound < 0
 +}
 +
 +func (t *Type) IsArray() bool {
 +      return t.Etype == TARRAY && t.Bound >= 0
 +}
 +
 +func (t *Type) IsStruct() bool {
 +      return t.Etype == TSTRUCT
 +}
 +
 +func (t *Type) IsInterface() bool {
 +      return t.Etype == TINTER
 +}
 +
 +func (t *Type) Elem() ssa.Type {
 +      return t.Type
 +}
 +func (t *Type) PtrTo() ssa.Type {
 +      return Ptrto(t)
 +}
 +
 +func (t *Type) NumFields() int64 {
 +      return int64(countfield(t))
 +}
 +func (t *Type) FieldType(i int64) ssa.Type {
 +      // TODO: store fields in a slice so we can
 +      // look them up by index in constant time.
 +      for t1 := t.Type; t1 != nil; t1 = t1.Down {
 +              if t1.Etype != TFIELD {
 +                      panic("non-TFIELD in a TSTRUCT")
 +              }
 +              if i == 0 {
 +                      return t1.Type
 +              }
 +              i--
 +      }
 +      panic("not enough fields")
 +}
 +func (t *Type) FieldOff(i int64) int64 {
 +      for t1 := t.Type; t1 != nil; t1 = t1.Down {
 +              if t1.Etype != TFIELD {
 +                      panic("non-TFIELD in a TSTRUCT")
 +              }
 +              if i == 0 {
 +                      return t1.Width
 +              }
 +              i--
 +      }
 +      panic("not enough fields")
 +}
 +
 +func (t *Type) NumElem() int64 {
 +      if t.Etype != TARRAY {
 +              panic("NumElem on non-TARRAY")
 +      }
 +      return int64(t.Bound)
 +}
 +
 +func (t *Type) IsMemory() bool { return false }
 +func (t *Type) IsFlags() bool  { return false }
 +func (t *Type) IsVoid() bool   { return false }

diff --cc src/cmd/compile/internal/gc/walk.go
Simple merge

diff --cc src/cmd/dist/buildtool.go
index b231b5ce6179fe2d01d6660c1353b74b83bbe21b,20d95353075355c492d2efd12e09d32cfdde865a..9b98bf27410b4d396b5f1da9bc191d75f5bc545c
--- 1/src/cmd/dist/buildtool.go
--- 2/src/cmd/dist/buildtool.go
+++ b/src/cmd/dist/buildtool.go
@@@ -34,8 -34,8 +34,9 @@@ var bootstrapDirs = []string
        "compile/internal/arm64",
        "compile/internal/big",
        "compile/internal/gc",
+       "compile/internal/mips64",
        "compile/internal/ppc64",
 +      "compile/internal/ssa",
        "compile/internal/x86",
        "internal/gcprog",
        "internal/obj",

diff --cc src/cmd/internal/obj/util.go
Simple merge

diff --cc src/cmd/internal/obj/x86/a.out.go
Simple merge

diff --cc src/cmd/internal/obj/x86/obj6.go
index 503971a40dbf230272c6471bdeb4ecf6cc931343,49fa22aef06c1addd2bcc76930915b46406aaf48..8775c5b354056d6d87dfcd3f6fb40405633fc6cd
--- 1/src/cmd/internal/obj/x86/obj6.go
--- 2/src/cmd/internal/obj/x86/obj6.go
+++ b/src/cmd/internal/obj/x86/obj6.go
@@@ -38,7 -38,17 +38,17 @@@ import 
        "math"
  )
  
 -func canuse1insntls(ctxt *obj.Link) bool {
 +func CanUse1InsnTLS(ctxt *obj.Link) bool {
+       if isAndroid {
+               // For android, we use a disgusting hack that assumes
+               // the thread-local storage slot for g is allocated
+               // using pthread_key_create with a fixed offset
+               // (see src/runtime/cgo/gcc_android_amd64.c).
+               // This makes access to the TLS storage (for g) doable
+               // with 1 instruction.
+               return true
+       }
+ 
        if ctxt.Arch.Regsize == 4 {
                switch ctxt.Headtype {
                case obj.Hlinux,

diff --cc src/runtime/malloc.go
index 4ce159c267756d513712d070ac73985bb364eb6f,d9f52399b8f2165795939ce231e9d7262fbf9355..b77c210f6f088748debf14c6fb1f2eb940fd4141
--- 1/src/runtime/malloc.go
--- 2/src/runtime/malloc.go
+++ b/src/runtime/malloc.go
@@@ -615,8 -618,8 +618,9 @@@ func mallocgc(size uintptr, typ *_type
                        (*[2]uint64)(x)[1] = 0
                        // See if we need to replace the existing tiny block with the new one
                        // based on amount of remaining free space.
-                       if size < c.tinyoffset {
-                               c.tiny = x
+                       if size < c.tinyoffset || c.tiny == nil {
 -                              c.tiny = x
++                              // TODO(khr): replace this with "c.tiny = x" when c.tiny use is fixed.
++                              writebarrierptr((*uintptr)(unsafe.Pointer(&c.tiny)), uintptr(x))
                                c.tinyoffset = size
                        }
                        size = maxTinySize

diff --cc src/runtime/mbarrier.go
Simple merge

diff --cc src/runtime/runtime-gdb_test.go
Simple merge

diff --cc src/runtime/stack.go
index 128278ebdcaa046acdd909b4661789f4a68422e7,00cd6aeb1dcc8625b6ccd5f5e0bc96cc71f35ff0..9a8afd66950af95574c5cf57915ebd4796c21372
--- 1/src/runtime/stack.go
--- 2/src/runtime/stack.go
+++ b/src/runtime/stack.go
@@@ -86,7 -90,7 +90,7 @@@ const 
  
        // The stack guard is a pointer this many bytes above the
        // bottom of the stack.
-       _StackGuard = 1024*stackGuardMultiplier + _StackSystem
 -      _StackGuard = 720*sys.StackGuardMultiplier + _StackSystem
++      _StackGuard = 1024*sys.StackGuardMultiplier + _StackSystem
  
        // After a stack split check the SP is allowed to be this
        // many bytes below the stack guard.  This saves an instruction

diff --cc test/fixedbugs/issue11590.go
index 0000000000000000000000000000000000000000,9776704b2a4964749604b1bb4ec5337d6f080178..1acac64c735d6f2eada994ca5570a1aaae86ef6f
mode 000000,100644..100644
--- /dev/null
--- 2/test/fixedbugs/issue11590.go
+++ b/test/fixedbugs/issue11590.go
@@@ -1,0 -1,11 +1,11 @@@
 -var _ = int8(4) * 300         // ERROR "constant overflows int8"
 -var _ = complex64(1) * 1e200  // ERROR "constant overflows complex64"
 -var _ = complex128(1) * 1e500 // ERROR "constant overflows complex128"
+ // errorcheck
+ 
+ // Copyright 2015 The Go Authors.  All rights reserved.
+ // Use of this source code is governed by a BSD-style
+ // license that can be found in the LICENSE file.
+ 
+ package p
+ 
++var _ = int8(4) * 300         // ERROR "constant 300 overflows int8" "constant 1200 overflows int8"
++var _ = complex64(1) * 1e200  // ERROR "constant 1e\+200 overflows complex64"
++var _ = complex128(1) * 1e500 // ERROR "constant 1\.00000e\+500 overflows complex128"

diff --cc test/nilptr3.go
index 33045207b21daf50562e8762f0c1ae73409ea415,6c8aab32cb57f33796c13e7e010a449b23a12553..1ba774d83966e1e79fa607b8ed4c212981771ee9
--- 1/test/nilptr3.go
--- 2/test/nilptr3.go
+++ b/test/nilptr3.go
@@@ -1,7 -1,8 +1,8 @@@
  // errorcheck -0 -d=nil
  // Fails on ppc64x because of incomplete optimization.
  // See issues 9058.
- // +build !ppc64,!ppc64le,!amd64
+ // Same reason for mips64x.
 -// +build !ppc64,!ppc64le,!mips64,!mips64le
++// +build !ppc64,!ppc64le,!mips64,!mips64le,!amd64
  
  // Copyright 2013 The Go Authors.  All rights reserved.
  // Use of this source code is governed by a BSD-style

diff --cc test/nosplit.go
Simple merge