miqt/cmd/genbindings/emitgo.go

808 lines
25 KiB
Go

package main
import (
"C"
"fmt"
"go/format"
"log"
"path"
"sort"
"strings"
)
func goReservedWord(s string) bool {
switch s {
case "default", "const", "func", "var", "type", "len", "new", "copy", "import", "range", "string", "map", "int", "select",
"ret": // not a language-reserved word, but a binding-reserved word
return true
default:
return false
}
}
func (p CppParameter) RenderTypeGo(gfs *goFileState) string {
if p.Pointer && p.ParameterType == "char" {
return "string"
}
if p.ParameterType == "QString" {
return "string"
}
if p.ParameterType == "QByteArray" {
return "[]byte"
}
if t, ok := p.QListOf(); ok {
return "[]" + t.RenderTypeGo(gfs)
}
if t, ok := p.QSetOf(); ok {
return "map[" + t.RenderTypeGo(gfs) + "]struct{}"
}
if p.ParameterType == "void" && p.Pointer {
return "unsafe.Pointer"
}
ret := ""
switch p.ParameterType {
case "unsigned char", "uchar", "quint8":
// Go byte is unsigned
ret += "byte"
case "char", "qint8", "signed char":
ret += "int8" // Signed
case "short", "qint16", "int16_t":
ret += "int16"
case "ushort", "quint16", "unsigned short", "uint16_t":
ret += "uint16"
case "long":
// Windows ILP32 - 32-bits
// Linux LP64 - 64-bits
if C.sizeof_long == 4 {
ret += "int32"
} else {
ret += "int64"
}
case "ulong", "unsigned long":
if C.sizeof_long == 4 {
ret += "uint32"
} else {
ret += "uint64"
}
case "unsigned int":
ret += "uint"
case "qint32":
ret += "int32"
case "quint32":
ret += "uint32"
case "qlonglong", "qint64", "long long":
ret += "int64"
case "qulonglong", "quint64", "unsigned long long":
ret += "uint64"
case "float":
ret += "float32"
case "double", "qreal":
ret += "float64"
case "size_t": // size_t is unsigned
if C.sizeof_size_t == 4 {
ret += "uint32"
} else {
ret += "uint64"
}
case "qsizetype", "QIntegerForSizeof<std::size_t>::Signed", "qptrdiff", "ptrdiff_t": // all signed
if C.sizeof_size_t == 4 {
ret += "int32"
} else {
ret += "int64"
}
case "qintptr", "uintptr_t", "intptr_t", "quintptr", "QIntegerForSizeof<void *>::Unsigned", "QIntegerForSizeof<void *>::Signed":
ret += "uintptr"
default:
if ft, ok := p.QFlagsOf(); ok {
if enumInfo, ok := KnownEnums[ft.ParameterType]; ok && enumInfo.PackageName != gfs.currentPackageName {
// Cross-package
ret += path.Base(enumInfo.PackageName) + "." + cabiClassName(ft.ParameterType)
gfs.imports[importPathForQtPackage(enumInfo.PackageName)] = struct{}{}
} else {
// Same package
ret += cabiClassName(ft.ParameterType)
}
} else if enumInfo, ok := KnownEnums[p.ParameterType]; ok {
if enumInfo.PackageName != gfs.currentPackageName {
// Cross-package
ret += path.Base(enumInfo.PackageName) + "." + cabiClassName(p.ParameterType)
gfs.imports[importPathForQtPackage(enumInfo.PackageName)] = struct{}{}
} else {
// Same package
ret += cabiClassName(p.ParameterType)
}
} else if strings.Contains(p.ParameterType, `::`) {
// Inner class
ret += cabiClassName(p.ParameterType)
} else {
// Do not transform this type
ret += p.ParameterType
}
}
if pkg, ok := KnownClassnames[p.ParameterType]; ok && pkg.PackageName != gfs.currentPackageName {
ret = path.Base(pkg.PackageName) + "." + ret
gfs.imports[importPathForQtPackage(pkg.PackageName)] = struct{}{}
}
if p.ByRef || p.Pointer {
ret = "*" + ret
}
return ret // ignore const
}
func (p CppParameter) parameterTypeCgo() string {
if p.ParameterType == "QString" {
return "C.struct_miqt_string"
}
if p.ParameterType == "QByteArray" {
return "C.struct_miqt_string"
}
if _, ok := p.QListOf(); ok {
return "*C.struct_miqt_array"
}
if _, ok := p.QSetOf(); ok {
return "*C.struct_miqt_array"
}
tmp := strings.Replace(p.RenderTypeCabi(), `*`, "", -1)
if strings.HasPrefix(tmp, "const ") && tmp != "const char" { // Special typedef to make this work for const char* signal parameters
tmp = tmp[6:] // Constness doesn't survive the CABI boundary
}
if strings.HasPrefix(tmp, "unsigned ") {
tmp = "u" + tmp[9:] // Cgo uses uchar, uint instead of full name
}
if strings.HasPrefix(tmp, "signed ") {
tmp = "s" + tmp[7:] // Cgo uses schar
}
tmp = strings.Replace(tmp, `long long`, `longlong`, -1)
tmp = "C." + strings.Replace(tmp, " ", "_", -1)
if p.QtClassType() || p.Pointer || p.ByRef {
return "*" + tmp
} else {
return tmp
}
}
func (gfs *goFileState) emitParametersGo(params []CppParameter) string {
tmp := make([]string, 0, len(params))
skipNext := false
for i, p := range params {
if IsArgcArgv(params, i) {
skipNext = true
tmp = append(tmp, "args []string")
} else if skipNext {
// Skip this parameter, already handled
skipNext = false
} else {
// Ordinary parameter
tmp = append(tmp, p.ParameterName+" "+p.RenderTypeGo(gfs))
}
}
return strings.Join(tmp, ", ")
}
type goFileState struct {
imports map[string]struct{}
currentPackageName string
}
func (gfs *goFileState) emitParametersGo2CABIForwarding(m CppMethod) (preamble string, forwarding string) {
tmp := make([]string, 0, len(m.Parameters)+2)
if !m.IsStatic {
tmp = append(tmp, "this.h")
}
skipNext := false
for i, p := range m.Parameters {
if IsArgcArgv(m.Parameters, i) {
skipNext = true
// QApplication constructor. Convert 'args' into Qt's wanted types
// Qt has a warning in the docs saying these pointers must be valid
// for the entire lifetype of QApplication, so, malloc + never free
// This transformation only affects the Go side. The CABI side is
// projected naturally
preamble += "// Convert []string to long-lived int& argc, char** argv, never call free()\n"
preamble += "argc := (*C.int)(C.malloc(8))\n"
preamble += "*argc = C.int(len(args))\n"
preamble += "argv := (*[0xffff]*C.char)(C.malloc(C.size_t(8 * len(args))))\n"
preamble += "for i := range args {\n"
preamble += "argv[i] = C.CString(args[i])\n"
preamble += "}\n"
tmp = append(tmp, "argc, &argv[0]")
} else if skipNext {
// Skip this parameter, already handled
skipNext = false
} else {
addPreamble, rvalue := gfs.emitParameterGo2CABIForwarding(p)
preamble += addPreamble
tmp = append(tmp, rvalue)
}
}
return preamble, strings.Join(tmp, ", ")
}
func (gfs *goFileState) emitParameterGo2CABIForwarding(p CppParameter) (preamble string, rvalue string) {
nameprefix := makeNamePrefix(p.ParameterName)
if p.ParameterType == "QString" {
// Go: convert string -> miqt_string*
// CABI: convert miqt_string* -> real QString
gfs.imports["unsafe"] = struct{}{}
preamble += nameprefix + "_ms := C.struct_miqt_string{}\n"
preamble += nameprefix + "_ms.data = C.CString(" + p.ParameterName + ")\n"
preamble += nameprefix + "_ms.len = C.size_t(len(" + p.ParameterName + "))\n"
preamble += "defer C.free(unsafe.Pointer(" + nameprefix + "_ms.data))\n"
rvalue = nameprefix + "_ms"
} else if p.ParameterType == "QByteArray" {
// Go: convert []byte -> miqt_string
// CABI: convert miqt_string -> QByteArray
// n.b. This can ALIAS the existing []byte data
gfs.imports["unsafe"] = struct{}{}
preamble += nameprefix + "_alias := C.struct_miqt_string{}\n"
preamble += nameprefix + "_alias.data = (*C.char)(unsafe.Pointer(&" + p.ParameterName + "[0]))\n"
preamble += nameprefix + "_alias.len = C.size_t(len(" + p.ParameterName + "))\n"
rvalue = nameprefix + "_alias"
} else if listType, ok := p.QListOf(); ok {
// QList<T>
// Go: convert T[] -> t* and len
// CABI: create a real QList<>
gfs.imports["runtime"] = struct{}{}
gfs.imports["unsafe"] = struct{}{}
var mallocSize string
if listType.ParameterType == "QString" || listType.ParameterType == "QByteArray" {
preamble += "// For the C ABI, malloc a C array of structs\n"
mallocSize = "int(unsafe.Sizeof(C.struct_miqt_string{}))"
} else {
preamble += "// For the C ABI, malloc a C array of raw pointers\n"
mallocSize = "8"
}
preamble += nameprefix + "_CArray := (*[0xffff]" + listType.parameterTypeCgo() + ")(C.malloc(C.size_t(" + mallocSize + " * len(" + p.ParameterName + "))))\n"
preamble += "defer C.free(unsafe.Pointer(" + nameprefix + "_CArray))\n"
preamble += "for i := range " + p.ParameterName + "{\n"
listType.ParameterName = p.ParameterName + "[i]"
addPreamble, innerRvalue := gfs.emitParameterGo2CABIForwarding(listType)
preamble += addPreamble
preamble += nameprefix + "_CArray[i] = " + innerRvalue + "\n"
preamble += "}\n"
preamble += p.ParameterName + "_ma := &C.struct_miqt_array{len: C.size_t(len(" + p.ParameterName + ")), data: unsafe.Pointer(" + nameprefix + "_CArray)}\n"
preamble += "defer runtime.KeepAlive(unsafe.Pointer(" + nameprefix + "_ma))\n"
rvalue = p.ParameterName + "_ma"
} else if _, ok := p.QSetOf(); ok {
panic("QSet<> arguments are not yet implemented") // n.b. doesn't seem to exist in QtCore/QtGui/QtWidgets at all
} else if p.Pointer && p.ParameterType == "char" {
// Single char* argument
gfs.imports["unsafe"] = struct{}{}
preamble += nameprefix + "_Cstring := C.CString(" + p.ParameterName + ")\n"
preamble += "defer C.free(unsafe.Pointer(" + nameprefix + "_Cstring))\n"
rvalue = nameprefix + "_Cstring"
} else if /*(p.Pointer || p.ByRef) &&*/ p.QtClassType() {
// The C++ type is a pointer to Qt class
// We want our functions to accept the Go wrapper type, and forward as cPointer()
// cPointer() returns the cgo pointer which only works in the same package -
// anything cross-package needs to go via unsafe.Pointer
if classInfo, ok := KnownClassnames[p.ParameterType]; ok && gfs.currentPackageName != classInfo.PackageName {
// Cross-package
rvalue = "(" + p.parameterTypeCgo() + ")(" + p.ParameterName + ".UnsafePointer())"
} else {
// Same package
rvalue = p.ParameterName + ".cPointer()"
}
} else if p.IntType() || p.IsFlagType() || p.IsKnownEnum() || p.ParameterType == "bool" {
if p.Pointer || p.ByRef {
gfs.imports["unsafe"] = struct{}{}
rvalue = "(" + p.parameterTypeCgo() + ")(unsafe.Pointer(" + p.ParameterName + "))" // n.b. This may not work if the integer type conversion was wrong
} else {
rvalue = "(" + p.parameterTypeCgo() + ")(" + p.ParameterName + ")"
}
} else {
// Default
rvalue = p.ParameterName
}
return preamble, rvalue
}
func (gfs *goFileState) emitCabiToGo(assignExpr string, rt CppParameter, rvalue string) string {
shouldReturn := assignExpr // "return "
afterword := ""
namePrefix := makeNamePrefix(rt.ParameterName)
if rt.ParameterType == "void" && !rt.Pointer {
shouldReturn = ""
return shouldReturn + " " + rvalue + "\n" + afterword
} else if rt.ParameterType == "void" && rt.Pointer {
gfs.imports["unsafe"] = struct{}{}
return assignExpr + " (unsafe.Pointer)(" + rvalue + ")\n"
} else if rt.ParameterType == "char" && rt.Pointer {
// Qt functions normally return QString - anything returning char*
// is something like QByteArray.Data() where it returns an unsafe
// internal pointer
// However in case this is a signal, we need to be able to marshal both
// forwards and backwards with the same types, this has to be a string
// in both cases
// This is not a miqt_string and therefore MIQT did not allocate it,
// and therefore we don't have to free it either
gfs.imports["unsafe"] = struct{}{}
shouldReturn = namePrefix + "_ret := "
afterword += assignExpr + " C.GoString(" + namePrefix + "_ret)\n"
return shouldReturn + " " + rvalue + "\n" + afterword
} else if rt.ParameterType == "QString" {
gfs.imports["unsafe"] = struct{}{}
shouldReturn = "var " + namePrefix + "_ms C.struct_miqt_string = "
afterword += namePrefix + "_ret := C.GoStringN(" + namePrefix + "_ms.data, C.int(int64(" + namePrefix + "_ms.len)))\n"
afterword += "C.free(unsafe.Pointer(" + namePrefix + "_ms.data))\n"
afterword += assignExpr + namePrefix + "_ret"
return shouldReturn + " " + rvalue + "\n" + afterword
} else if rt.ParameterType == "QByteArray" {
// We receive the CABI type of a miqt_string. Convert it into []byte
// We must free the miqt_string data pointer - this is a data copy,
// not an alias
gfs.imports["unsafe"] = struct{}{}
shouldReturn = "var " + namePrefix + "_bytearray C.struct_miqt_string = "
afterword += namePrefix + "_ret := C.GoBytes(unsafe.Pointer(" + namePrefix + "_bytearray.data), C.int(int64(" + namePrefix + "_bytearray.len)))\n"
afterword += "C.free(unsafe.Pointer(" + namePrefix + "_bytearray.data))\n"
afterword += assignExpr + namePrefix + "_ret"
return shouldReturn + " " + rvalue + "\n" + afterword
} else if t, ok := rt.QListOf(); ok {
gfs.imports["unsafe"] = struct{}{}
shouldReturn = "var " + namePrefix + "_ma *C.struct_miqt_array = "
afterword += namePrefix + "_ret := make([]" + t.RenderTypeGo(gfs) + ", int(" + namePrefix + "_ma.len))\n"
afterword += namePrefix + "_outCast := (*[0xffff]" + t.parameterTypeCgo() + ")(unsafe.Pointer(" + namePrefix + "_ma.data)) // hey ya\n"
afterword += "for i := 0; i < int(" + namePrefix + "_ma.len); i++ {\n"
afterword += gfs.emitCabiToGo(namePrefix+"_ret[i] = ", t, namePrefix+"_outCast[i]")
afterword += "}\n"
afterword += "C.free(unsafe.Pointer(" + namePrefix + "_ma))\n"
afterword += assignExpr + " " + namePrefix + "_ret\n"
return shouldReturn + " " + rvalue + "\n" + afterword
} else if t, ok := rt.QSetOf(); ok {
gfs.imports["unsafe"] = struct{}{}
shouldReturn = "var " + namePrefix + "_ma *C.struct_miqt_array = "
afterword += namePrefix + "_ret := make(map[" + t.RenderTypeGo(gfs) + "]struct{}, int(" + namePrefix + "_ma.len))\n"
afterword += namePrefix + "_outCast := (*[0xffff]" + t.parameterTypeCgo() + ")(unsafe.Pointer(" + namePrefix + "_ma.data)) // hey ya\n"
afterword += "for i := 0; i < int(" + namePrefix + "_ma.len); i++ {\n"
afterword += gfs.emitCabiToGo(namePrefix+"_element := ", t, namePrefix+"_outCast[i]") + "\n"
afterword += namePrefix + "_ret[" + namePrefix + "_element] = struct{}{}\n"
afterword += "}\n"
afterword += "C.free(unsafe.Pointer(" + namePrefix + "_ma))\n"
afterword += assignExpr + " " + namePrefix + "_ret\n"
return shouldReturn + " " + rvalue + "\n" + afterword
} else if rt.QtClassType() {
// Construct our Go type based on this inner CABI type
shouldReturn = "" + namePrefix + "_ret := "
crossPackage := ""
if pkg, ok := KnownClassnames[rt.ParameterType]; ok && pkg.PackageName != gfs.currentPackageName {
crossPackage = path.Base(pkg.PackageName) + "."
gfs.imports[importPathForQtPackage(pkg.PackageName)] = struct{}{}
}
if rt.Pointer || rt.ByRef {
gfs.imports["unsafe"] = struct{}{}
return assignExpr + " " + crossPackage + "UnsafeNew" + cabiClassName(rt.ParameterType) + "(unsafe.Pointer(" + rvalue + "))"
} else {
// This is return by value, but CABI has new'd it into a
// heap type for us
// To preserve Qt's approximate semantics, add a runtime
// finalizer to automatically Delete once the type goes out
// of Go scope
if crossPackage == "" {
afterword += namePrefix + "_goptr := new" + cabiClassName(rt.ParameterType) + "(" + namePrefix + "_ret)\n"
} else {
gfs.imports["unsafe"] = struct{}{}
afterword += namePrefix + "_goptr := " + crossPackage + "UnsafeNew" + cabiClassName(rt.ParameterType) + "(unsafe.Pointer(" + namePrefix + "_ret))\n"
}
afterword += namePrefix + "_goptr.GoGC() // Qt uses pass-by-value semantics for this type. Mimic with finalizer\n"
// If this is a function return, we have converted value-returned Qt types to pointers
// If this is a slot return, we haven't
// TODO standardize this
if strings.Contains(assignExpr, `return`) {
afterword += assignExpr + "" + namePrefix + "_goptr\n"
} else {
afterword += assignExpr + " *" + namePrefix + "_goptr\n"
}
}
return shouldReturn + " " + rvalue + "\n" + afterword
} else if rt.IntType() || rt.IsKnownEnum() || rt.IsFlagType() || rt.ParameterType == "bool" || rt.QtCppOriginalType != nil {
// Need to cast Cgo type to Go int type
// Optimize assignment to avoid temporary
return assignExpr + "(" + rt.RenderTypeGo(gfs) + ")(" + rvalue + ")\n"
} else {
panic(fmt.Sprintf("emitgo::emitCabiToGo missing type handler for parameter %+v", rt))
}
}
func emitGo(src *CppParsedHeader, headerName string, packageName string) (string, error) {
ret := strings.Builder{}
ret.WriteString(`package ` + path.Base(packageName) + `
/*
#include "gen_` + headerName + `"
#include <stdlib.h>
*/
import "C"
%%_IMPORTLIBS_%%
`)
gfs := goFileState{
imports: map[string]struct{}{},
currentPackageName: packageName,
}
// Check if short-named enums are allowed.
// We only allow short names if there are no conflicts anywhere in the whole
// file. This doesn't fully defend against cross-file conflicts but those
// should hopefully be rare enough
preventShortNames := map[string]struct{}{}
{
nameTest := map[string]string{}
nextEnum:
for _, e := range src.Enums {
shortEnumName := e.ShortEnumName()
// Disallow entry<-->entry collisions
for _, ee := range e.Entries {
if other, ok := nameTest[shortEnumName+"::"+ee.EntryName]; ok {
preventShortNames[e.EnumName] = struct{}{} // Our full enum name
preventShortNames[other] = struct{}{} // Their full enum name
continue nextEnum
}
nameTest[shortEnumName+"::"+ee.EntryName] = e.EnumName
if _, ok := KnownClassnames[shortEnumName+"::"+ee.EntryName]; ok {
preventShortNames[e.EnumName] = struct{}{}
continue nextEnum
}
}
}
}
for _, e := range src.Enums {
if e.EnumName == "" {
continue // Removed by transformRedundant AST pass
}
goEnumName := cabiClassName(e.EnumName) // Fully qualified name of the enum itself
goEnumShortName := goEnumName // Shorter name, so that enum elements are reachable from the surrounding namespace
if _, ok := preventShortNames[e.EnumName]; !ok {
goEnumShortName = cabiClassName(e.ShortEnumName())
}
ret.WriteString(`
type ` + goEnumName + ` ` + e.UnderlyingType.RenderTypeGo(&gfs) + `
`)
if len(e.Entries) > 0 {
ret.WriteString("const (\n")
for _, ee := range e.Entries {
ret.WriteString(titleCase(cabiClassName(goEnumShortName+"::"+ee.EntryName)) + " " + goEnumName + " = " + ee.EntryValue + "\n")
}
ret.WriteString("\n)\n\n")
}
}
for _, c := range src.Classes {
goClassName := cabiClassName(c.ClassName)
ret.WriteString(`
type ` + goClassName + ` struct {
h *C.` + goClassName + `
`)
// Embed all inherited types to directly allow calling inherited methods
for _, base := range c.Inherits {
if pkg, ok := KnownClassnames[base]; ok && pkg.PackageName != gfs.currentPackageName {
// Cross-package parent class
ret.WriteString("*" + path.Base(pkg.PackageName) + "." + cabiClassName(base) + "\n")
gfs.imports[importPathForQtPackage(pkg.PackageName)] = struct{}{}
} else {
// Same-package parent class
ret.WriteString("*" + cabiClassName(base) + "\n")
}
}
ret.WriteString(`
}
func (this *` + goClassName + `) cPointer() *C.` + goClassName + ` {
if this == nil {
return nil
}
return this.h
}
func (this *` + goClassName + `) UnsafePointer() unsafe.Pointer {
if this == nil {
return nil
}
return unsafe.Pointer(this.h)
}
`)
gfs.imports["unsafe"] = struct{}{}
localInit := "h: h"
for _, base := range c.Inherits {
gfs.imports["unsafe"] = struct{}{}
ctorPrefix := ""
if pkg, ok := KnownClassnames[base]; ok && pkg.PackageName != gfs.currentPackageName {
ctorPrefix = path.Base(pkg.PackageName) + "."
}
localInit += ", " + cabiClassName(base) + ": " + ctorPrefix + "UnsafeNew" + cabiClassName(base) + "(unsafe.Pointer(h))"
}
ret.WriteString(`
func new` + goClassName + `(h *C.` + goClassName + `) *` + goClassName + ` {
if h == nil {
return nil
}
return &` + goClassName + `{` + localInit + `}
}
`)
// CGO types only exist within the same Go file, so other Go files can't
// call this same private ctor function, unless it goes through unsafe.Pointer{}.
// This is probably because C types can possibly violate the ODR whereas
// that never happens in Go's type system.
gfs.imports["unsafe"] = struct{}{}
ret.WriteString(`
func UnsafeNew` + goClassName + `(h unsafe.Pointer) *` + goClassName + ` {
return new` + goClassName + `( (*C.` + goClassName + `)(h) )
}
`)
for i, ctor := range c.Ctors {
preamble, forwarding := gfs.emitParametersGo2CABIForwarding(ctor)
if ctor.LinuxOnly {
gfs.imports["runtime"] = struct{}{}
ret.WriteString(`
// New` + goClassName + maybeSuffix(i) + ` constructs a new ` + c.ClassName + ` object.
func New` + goClassName + maybeSuffix(i) + `(` + gfs.emitParametersGo(ctor.Parameters) + `) *` + goClassName + ` {
if runtime.GOOS == "linux" {
` + preamble + ` ret := C.` + goClassName + `_new` + maybeSuffix(i) + `(` + forwarding + `)
return new` + goClassName + `(ret)
} else {
panic("Unsupported OS")
}
}
`)
} else {
ret.WriteString(`
// New` + goClassName + maybeSuffix(i) + ` constructs a new ` + c.ClassName + ` object.
func New` + goClassName + maybeSuffix(i) + `(` + gfs.emitParametersGo(ctor.Parameters) + `) *` + goClassName + ` {
` + preamble + ` ret := C.` + goClassName + `_new` + maybeSuffix(i) + `(` + forwarding + `)
return new` + goClassName + `(ret)
}
`)
}
}
for _, m := range c.Methods {
preamble, forwarding := gfs.emitParametersGo2CABIForwarding(m)
returnTypeDecl := m.ReturnType.RenderTypeGo(&gfs)
if returnTypeDecl == "void" {
returnTypeDecl = ""
}
if m.ReturnType.QtClassType() && m.ReturnType.ParameterType != "QString" && m.ReturnType.ParameterType != "QByteArray" && !(m.ReturnType.Pointer || m.ReturnType.ByRef) {
returnTypeDecl = "*" + returnTypeDecl
}
rvalue := `C.` + goClassName + `_` + m.SafeMethodName() + `(` + forwarding + `)`
returnFunc := gfs.emitCabiToGo("return ", m.ReturnType, rvalue)
receiverAndMethod := `(this *` + goClassName + `) ` + m.SafeMethodName()
if m.IsStatic {
receiverAndMethod = goClassName + `_` + m.SafeMethodName()
}
ret.WriteString(`
func ` + receiverAndMethod + `(` + gfs.emitParametersGo(m.Parameters) + `) ` + returnTypeDecl + ` {`)
if m.LinuxOnly {
gfs.imports["runtime"] = struct{}{}
ret.WriteString(`
if runtime.GOOS != "linux" {
panic("Unsupported OS")
}
`)
}
ret.WriteString(`
` + preamble +
returnFunc + `}
`)
// Add Connect() wrappers for signal functions
if m.IsSignal {
gfs.imports["unsafe"] = struct{}{}
gfs.imports["runtime/cgo"] = struct{}{}
var cgoNamedParams []string
var paramNames []string
conversion := ""
if len(m.Parameters) > 0 {
conversion = "// Convert all CABI parameters to Go parameters\n"
}
for i, pp := range m.Parameters {
cgoNamedParams = append(cgoNamedParams, pp.ParameterName+" "+pp.parameterTypeCgo())
paramNames = append(paramNames, fmt.Sprintf("slotval%d", i+1))
conversion += gfs.emitCabiToGo(fmt.Sprintf("slotval%d := ", i+1), pp, pp.ParameterName) + "\n"
}
ret.WriteString(`func (this *` + goClassName + `) On` + m.SafeMethodName() + `(slot func(` + gfs.emitParametersGo(m.Parameters) + `)) {
C.` + goClassName + `_connect_` + m.SafeMethodName() + `(this.h, C.intptr_t(cgo.NewHandle(slot)) )
}
//export miqt_exec_callback_` + goClassName + `_` + m.SafeMethodName() + `
func miqt_exec_callback_` + goClassName + `_` + m.SafeMethodName() + `(cb C.intptr_t` + ifv(len(m.Parameters) > 0, ", ", "") + strings.Join(cgoNamedParams, `, `) + `) {
gofunc, ok := cgo.Handle(cb).Value().(func(` + gfs.emitParametersGo(m.Parameters) + `))
if !ok {
panic("miqt: callback of non-callback type (heap corruption?)")
}
` + conversion + `
gofunc(` + strings.Join(paramNames, `, `) + ` )
}
`)
}
}
if c.CanDelete {
gfs.imports["runtime"] = struct{}{} // Finalizer
ret.WriteString(`
// Delete this object from C++ memory.
func (this *` + goClassName + `) Delete() {
C.` + goClassName + `_Delete(this.h)
}
// GoGC adds a Go Finalizer to this pointer, so that it will be deleted
// from C++ memory once it is unreachable from Go memory.
func (this *` + goClassName + `) GoGC() {
runtime.SetFinalizer(this, func(this *` + goClassName + `) {
this.Delete()
runtime.KeepAlive(this.h)
})
}
`)
}
}
goSrc := ret.String()
// Fixup imports
if len(gfs.imports) > 0 {
allImports := make([]string, 0, len(gfs.imports))
for k, _ := range gfs.imports {
if k == "libmiqt" {
allImports = append(allImports, `"`+BaseModule+`/libmiqt"`)
} else {
allImports = append(allImports, `"`+k+`"`)
}
}
sort.Strings(allImports)
goSrc = strings.Replace(goSrc, `%%_IMPORTLIBS_%%`, "import (\n\t"+strings.Join(allImports, "\n\t")+"\n)", 1)
} else {
goSrc = strings.Replace(goSrc, `%%_IMPORTLIBS_%%`, "", 1)
}
// Run gofmt over the result
formattedSrc, err := format.Source([]byte(goSrc))
if err != nil {
log.Printf("gofmt failure: %v", err)
formattedSrc = []byte(goSrc)
}
return string(formattedSrc), nil
}