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miqt/cmd/genbindings/emitcabi.go

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package main
import (
"fmt"
"sort"
"strings"
)
func (p CppParameter) RenderTypeCabi() string {
ret := p.ParameterType
switch p.ParameterType {
case "uchar":
ret = "unsigned char"
case "uint":
ret = "unsigned int"
case "ulong":
ret = "unsigned long"
case "qint8":
ret = "int8_t"
case "quint8":
ret = "uint8_t"
case "qint16", "short":
ret = "int16_t"
case "quint16", "ushort", "unsigned short":
ret = "uint16_t"
case "qint32":
ret = "int32_t"
case "quint32":
ret = "uint32_t"
case "qlonglong", "qint64":
ret = "int64_t"
case "qulonglong", "quint64":
ret = "uint64_t"
case "qfloat16":
ret = "_Float16" // No idea where this typedef comes from, but it exists
case "qsizetype":
ret = "size_t"
case "qreal":
ret = "double"
case "qintptr":
ret = "intptr_t"
case "quintptr", "uintptr":
ret = "uintptr_t"
case "qptrdiff":
ret = "ptrdiff_t"
}
if p.Const {
// This is needed for const-correctness for calling some overloads
// e.g. QShortcut ctor taking (QWidget* parent, const char* member) signal -
// the signal/slot requires that member is const, not just plain char*
ret = "const " + ret
}
if p.IsFlagType() {
ret = "int"
} else if strings.Contains(p.ParameterType, `::`) {
if p.IsEnum() {
ret = "uintptr_t"
} else {
// Inner class
ret = cabiClassName(p.ParameterType)
}
}
if p.Pointer {
ret += strings.Repeat("*", p.PointerCount)
} else if p.ByRef {
ret += "*"
}
return ret // ignore const
}
func emitReturnTypeCabi(p CppParameter) string {
if p.ParameterType == "QString" {
return "void" // Will be handled separately
} else if _, ok := p.QListOf(); ok {
return "void" // Will be handled separately
} else if (p.Pointer || p.ByRef) && p.QtClassType() {
return cabiClassName(p.ParameterType) + "*" // CABI type
} else if p.QtClassType() && !p.Pointer {
// Even if C++ returns by value, CABI is returning a heap copy (new'd, not malloc'd)
return cabiClassName(p.ParameterType) + "*" // CABI type
// return "void" // Handled separately with an _out pointer
} else {
return p.RenderTypeCabi()
}
}
func (p CppParameter) RenderTypeQtCpp() string {
cppType := p.UnderlyingType()
if p.Const {
cppType = "const " + cppType
}
if p.Pointer {
cppType += strings.Repeat("*", p.PointerCount)
}
if p.ByRef {
cppType += "&"
}
return cppType
}
// emitParametersCpp emits the parameter definitions exactly how Qt C++ defines them.
func emitParametersCpp(m CppMethod) string {
tmp := make([]string, 0, len(m.Parameters))
for _, p := range m.Parameters {
tmp = append(tmp, p.RenderTypeQtCpp()+" "+p.ParameterName)
}
return strings.Join(tmp, `, `)
}
func emitParameterTypesCpp(m CppMethod) string {
tmp := make([]string, 0, len(m.Parameters))
for _, p := range m.Parameters {
tmp = append(tmp, p.RenderTypeQtCpp())
}
return strings.Join(tmp, `, `)
}
func emitParametersCabi(m CppMethod, selfType string) string {
tmp := make([]string, 0, len(m.Parameters)+1)
if !m.IsStatic && selfType != "" {
tmp = append(tmp, selfType+" self")
}
for _, p := range m.Parameters {
if p.ParameterType == "QString" {
// The Go code has called this with two arguments: char* and len
// Declare that we take two parameters
tmp = append(tmp, "const char* "+p.ParameterName+", size_t "+p.ParameterName+"_Strlen")
} else if t, ok := p.QListOf(); ok {
if t.ParameterType == "QString" {
// Combo
tmp = append(tmp, "char** "+p.ParameterName+", uint64_t* "+p.ParameterName+"_Lengths, size_t "+p.ParameterName+"_len")
} else if t.QtClassType() && !t.Pointer {
// The Go code can only work with Qt types as pointers, so the CABI needs to take an array of
// pointers, not an array of values
// Needs one more level of indirection
tmp = append(tmp, t.RenderTypeCabi()+"** "+p.ParameterName+", size_t "+p.ParameterName+"_len")
} else {
// The Go code has called this with two arguments: T* and len
// Declare that we take two parameters
tmp = append(tmp, t.RenderTypeCabi()+"* "+p.ParameterName+", size_t "+p.ParameterName+"_len")
}
} else if p.QtClassType() {
if p.ByRef || p.Pointer {
// Pointer to Qt type
// Replace with taking our PQ typedef by value
tmp = append(tmp, cabiClassName(p.ParameterType)+"* "+p.ParameterName)
} else {
// Qt type passed by value
// The CABI will unconditionally take these by pointer and dereference them
// when passing to C++
tmp = append(tmp, cabiClassName(p.ParameterType)+"* "+p.ParameterName)
}
} else {
// RenderTypeCabi renders both pointer+reference as pointers
tmp = append(tmp, p.RenderTypeCabi()+" "+p.ParameterName)
}
}
// If the return type is QString, we need to handle returns via extra CABI
// parameters
// Qt C++: memory is in QString RAII
// CABI: memory is moved into C.malloc/C.free
// Go: converted to native Go string
if m.ReturnType.ParameterType == "QString" {
// Normally we would use size_t for a strlen, but Go calls C.GoStringN which takes a C.int
tmp = append(tmp, "char** _out, int* _out_Strlen")
} else if t, ok := m.ReturnType.QListOf(); ok {
// +1 pointer indirection since it's a heap array
// +1 pointer indirection for mutating remote parameter
// = 3 for char*, 2 for most types
// Maybe: +1 pointer indirection if we have to lift stack types to the heap
if t.ParameterType == "QString" {
// Combo
tmp = append(tmp, "char*** _out, int** _out_Lengths, size_t* _out_len") // Each length is a C.int for C.GoStringN use
} else if t.QtClassType() && !t.Pointer {
// QList<QByteArray> QByteArray::Split()
// We need to pointer-ify each of the interior elements too
tmp = append(tmp, t.RenderTypeCabi()+"*** _out, size_t* _out_len")
} else {
tmp = append(tmp, t.RenderTypeCabi()+"** _out, size_t* _out_len")
}
}
return strings.Join(tmp, ", ")
}
func emitParametersCABI2CppForwarding(params []CppParameter) (preamble string, forwarding string) {
tmp := make([]string, 0, len(params)+1)
for _, p := range params {
if p.ParameterType == "QString" {
// The CABI has accepted two parameters - need to convert to one real QString
// Create it on the stack
preamble += "\tQString " + p.ParameterName + "_QString = QString::fromUtf8(" + p.ParameterName + ", " + p.ParameterName + "_Strlen);\n"
tmp = append(tmp, p.ParameterName+"_QString")
} else if listType, ok := p.QListOf(); ok {
if listType.ParameterType == "QString" {
// Combo (3 parameters)
preamble += "\t" + p.ParameterType + " " + p.ParameterName + "_QList;\n"
preamble += "\t" + p.ParameterName + "_QList.reserve(" + p.ParameterName + "_len);\n"
preamble += "\tfor(size_t i = 0; i < " + p.ParameterName + "_len; ++i) {\n"
preamble += "\t\t" + p.ParameterName + "_QList.push_back(QString::fromUtf8(" + p.ParameterName + "[i], " + p.ParameterName + "_Lengths[i]));\n"
preamble += "\t}\n"
tmp = append(tmp, p.ParameterName+"_QList")
} else {
// The CABI has accepted two parameters - need to convert to one real QList<>
// Create it on the stack
preamble += "\t" + p.ParameterType + " " + p.ParameterName + "_QList;\n"
preamble += "\t" + p.ParameterName + "_QList.reserve(" + p.ParameterName + "_len);\n"
preamble += "\tfor(size_t i = 0; i < " + p.ParameterName + "_len; ++i) {\n"
if listType.QtClassType() && !listType.Pointer {
preamble += "\t\t" + p.ParameterName + "_QList.push_back(*(" + p.ParameterName + "[i]));\n"
} else if listType.IsFlagType() {
preamble += "\t\t" + p.ParameterName + "_QList.push_back(static_cast<" + listType.RenderTypeQtCpp() + ">(" + p.ParameterName + "[i]));\n"
} else {
preamble += "\t\t" + p.ParameterName + "_QList.push_back(" + p.ParameterName + "[i]);\n"
}
preamble += "\t}\n"
tmp = append(tmp, p.ParameterName+"_QList")
}
} else if p.IntType() {
// Use the raw ParameterType to select an explicit integer overload
// Don't use RenderTypeCabi() since it canonicalizes some int types for CABI
castSrc := p.ParameterName
castType := p.RenderTypeQtCpp()
if p.ByRef { // e.g. QDataStream::operator>>() overloads
castSrc = "*" + castSrc
}
if p.ParameterType == "qint64" ||
p.ParameterType == "quint64" ||
p.ParameterType == "qlonglong" ||
p.ParameterType == "qulonglong" ||
p.ParameterType == "qint8" {
// QDataStream::operator>>() by reference (qint64)
// QLockFile::getLockInfo() by pointer
// QTextStream::operator>>() by reference (qlonglong + qulonglong)
// QDataStream::operator>>() qint8
// CABI has these as int64_t* (long int) which fails a static_cast to qint64& (long long int&)
// Hack a hard C-style cast
tmp = append(tmp, "("+castType+")("+castSrc+")")
} else {
// Use static_cast<> safely
tmp = append(tmp, "static_cast<"+castType+">("+castSrc+")")
}
} else if p.ByRef {
if p.Pointer {
// By ref and by pointer
// This happens for QDataStream &QDataStream::operator>>(char *&s)
// We are only using one level of indirection
tmp = append(tmp, p.ParameterName)
} else {
// By ref and not by pointer
// We changed RenderTypeCabi() to render this as a pointer
// Need to dereference so we can pass as reference to the actual Qt C++ function
//tmp = append(tmp, "*"+p.ParameterName)
tmp = append(tmp, "*"+p.ParameterName)
}
} else if p.QtClassType() && !p.Pointer {
// CABI takes all Qt types by pointer, even if C++ wants them by value
// Dereference the passed-in pointer
tmp = append(tmp, "*"+p.ParameterName)
// } else if p.QtClassType() && p.Pointer {
// We need this static_cast<> anyway to convert from PQt (void*) to
// the real Qt type
// tmp = append(tmp, "static_cast<"+p.ParameterType+"*>("+p.ParameterName+")")
} else {
tmp = append(tmp, p.ParameterName)
}
}
return preamble, strings.Join(tmp, ", ")
}
// getReferencedTypes finds all referenced Qt types in this file.
func getReferencedTypes(src *CppParsedHeader) []string {
foundTypes := map[string]struct{}{}
for _, c := range src.Classes {
foundTypes[c.ClassName] = struct{}{}
for _, ctor := range c.Ctors {
for _, p := range ctor.Parameters {
if p.QtClassType() {
foundTypes[p.ParameterType] = struct{}{}
}
if t, ok := p.QListOf(); ok {
foundTypes["QList"] = struct{}{} // FIXME or QVector?
if t.QtClassType() {
foundTypes[t.ParameterType] = struct{}{}
}
}
}
}
for _, m := range c.Methods {
for _, p := range m.Parameters {
if p.QtClassType() {
foundTypes[p.ParameterType] = struct{}{}
}
if t, ok := p.QListOf(); ok {
foundTypes["QList"] = struct{}{} // FIXME or QVector?
if t.QtClassType() {
foundTypes[t.ParameterType] = struct{}{}
}
}
}
if m.ReturnType.QtClassType() {
foundTypes[m.ReturnType.ParameterType] = struct{}{}
}
if t, ok := m.ReturnType.QListOf(); ok {
foundTypes["QList"] = struct{}{} // FIXME or QVector?
if t.QtClassType() {
foundTypes[t.ParameterType] = struct{}{}
}
}
}
}
// Some types (e.g. QRgb) are found but are typedefs, not classes
for _, td := range src.Typedefs {
delete(foundTypes, td.Alias)
}
// Convert to sorted list
foundTypesList := make([]string, 0, len(foundTypes))
for ft := range foundTypes {
if strings.HasPrefix(ft, "QList<") || strings.HasPrefix(ft, "QVector<") {
continue
}
if strings.HasSuffix(ft, "Private") { // qbrush.h finds QGradientPrivate
continue
}
foundTypesList = append(foundTypesList, ft)
}
sort.Strings(foundTypesList)
return foundTypesList
}
// cabiClassName returns the Go / CABI class name for a Qt C++ class.
// Normally this is the same, except for class types that are nested inside another class definition.
func cabiClassName(className string) string {
// Must use __ to avoid subclass/method name collision e.g. QPagedPaintDevice::Margins
return strings.Replace(className, `::`, `__`, -1)
}
func emitBindingHeader(src *CppParsedHeader, filename string) (string, error) {
ret := strings.Builder{}
includeGuard := "GEN_" + strings.ToUpper(strings.Replace(filename, `.`, `_`, -1))
ret.WriteString(`#ifndef ` + includeGuard + `
#define ` + includeGuard + `
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#pragma GCC diagnostic ignored "-Wdeprecated-declarations"
#ifdef __cplusplus
extern "C" {
#endif
`)
foundTypesList := getReferencedTypes(src)
ret.WriteString("#ifdef __cplusplus\n")
for _, ft := range foundTypesList {
if ft == "QList" || ft == "QString" { // These types are reprojected
continue
}
if strings.Contains(ft, `::`) {
// Forward declarations of inner classes are not yet supported in C++
// @ref https://stackoverflow.com/q/1021793
ret.WriteString(`#if defined(WORKAROUND_INNER_CLASS_DEFINITION_` + cabiClassName(ft) + ")\n")
ret.WriteString(`typedef ` + ft + " " + cabiClassName(ft) + ";\n")
ret.WriteString("#else\n")
ret.WriteString(`class ` + cabiClassName(ft) + ";\n")
ret.WriteString("#endif\n")
} else {
ret.WriteString(`class ` + ft + ";\n")
}
}
ret.WriteString("#else\n")
for _, ft := range foundTypesList {
if ft == "QList" || ft == "QString" { // These types are reprojected
continue
}
ret.WriteString(`typedef struct ` + cabiClassName(ft) + " " + cabiClassName(ft) + ";\n")
}
ret.WriteString("#endif\n")
ret.WriteString("\n")
for _, c := range src.Classes {
cClassName := cabiClassName(c.ClassName)
for i, ctor := range c.Ctors {
ret.WriteString(fmt.Sprintf("%s %s_new%s(%s);\n", cClassName+"*", cClassName, maybeSuffix(i), emitParametersCabi(ctor, "")))
}
for _, m := range c.Methods {
ret.WriteString(fmt.Sprintf("%s %s_%s(%s);\n", emitReturnTypeCabi(m.ReturnType), cClassName, m.SafeMethodName(), emitParametersCabi(m, cClassName+"*")))
if m.IsSignal && !m.HasHiddenParams {
ret.WriteString(fmt.Sprintf("%s %s_connect_%s(%s* self, void* slot);\n", emitReturnTypeCabi(m.ReturnType), cClassName, m.SafeMethodName(), cClassName))
}
}
// delete
if c.CanDelete {
ret.WriteString(fmt.Sprintf("void %s_Delete(%s* self);\n", cClassName, cClassName))
}
ret.WriteString("\n")
}
ret.WriteString(
`#ifdef __cplusplus
} /* extern C */
#endif
#endif
`)
return ret.String(), nil
}
func emitBindingCpp(src *CppParsedHeader, filename string) (string, error) {
ret := strings.Builder{}
for _, ref := range getReferencedTypes(src) {
if !ImportHeaderForClass(ref) {
continue
}
if ref == "QString" {
ret.WriteString("#include <QString>\n")
ret.WriteString("#include <QByteArray>\n")
ret.WriteString("#include <cstring>\n")
continue
}
if strings.Contains(ref, `::`) {
ret.WriteString(`#define WORKAROUND_INNER_CLASS_DEFINITION_` + cabiClassName(ref) + "\n")
continue
}
ret.WriteString(`#include <` + ref + ">\n")
}
ret.WriteString(`#include "` + filename + "\"\n\n")
ret.WriteString(`#include "gen_` + filename + "\"\n")
ret.WriteString(`
extern "C" {
extern void miqt_exec_callback(void* cb, int argc, void* argv);
}
`)
for _, c := range src.Classes {
cClassName := cabiClassName(c.ClassName)
for i, ctor := range c.Ctors {
preamble, forwarding := emitParametersCABI2CppForwarding(ctor.Parameters)
if ctor.LinuxOnly {
ret.WriteString(fmt.Sprintf(
"%s* %s_new%s(%s) {\n"+
"#ifdef Q_OS_LINUX\n"+
"%s"+
"\treturn new %s(%s);\n"+
"#else\n"+
"\treturn nullptr;\n"+
"#endif\n"+
"}\n"+
"\n",
cClassName, cClassName, maybeSuffix(i), emitParametersCabi(ctor, ""),
preamble,
c.ClassName, forwarding,
))
} else {
ret.WriteString(fmt.Sprintf(
"%s* %s_new%s(%s) {\n"+
"%s"+
"\treturn new %s(%s);\n"+
"}\n"+
"\n",
cClassName, cClassName, maybeSuffix(i), emitParametersCabi(ctor, ""),
preamble,
c.ClassName, forwarding,
))
}
}
for _, m := range c.Methods {
// Need to take an extra 'self' parameter
shouldReturn := "return "
afterCall := ""
if m.ReturnType.ParameterType == "void" && !m.ReturnType.Pointer {
shouldReturn = ""
} else if m.ReturnType.ParameterType == "QString" {
if m.ReturnType.Pointer {
// e.g. QTextStream::String()
// These are rare, and probably expected to be lightweight references
// But, a copy is the best we can project it as
// Un-pointer-ify
shouldReturn = "QString* ret = "
afterCall = "\t// Convert QString pointer from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory\n"
afterCall += "\tQByteArray b = ret->toUtf8();\n"
} else {
shouldReturn = "QString ret = "
afterCall = "\t// Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory\n"
afterCall += "\tQByteArray b = ret.toUtf8();\n"
}
if m.ReturnType.Const {
shouldReturn = "const " + shouldReturn
}
afterCall += "\t*_out = static_cast<char*>(malloc(b.length()));\n"
afterCall += "\tmemcpy(*_out, b.data(), b.length());\n"
afterCall += "\t*_out_Strlen = b.length();\n"
} else if t, ok := m.ReturnType.QListOf(); ok {
if t.ParameterType == "QString" {
// Combo
// "char** _out, int64_t* _out_Lengths, size_t* _out_len")
shouldReturn = m.ReturnType.RenderTypeQtCpp() + " ret = "
afterCall += "\t// Convert QStringList from C++ memory to manually-managed C memory\n"
afterCall += "\tchar** __out = static_cast<char**>(malloc(sizeof(char*) * ret.length()));\n"
afterCall += "\tint* __out_Lengths = static_cast<int*>(malloc(sizeof(int) * ret.length()));\n"
afterCall += "\tfor (size_t i = 0, e = ret.length(); i < e; ++i) {\n"
afterCall += "\t\t// Convert QString from UTF-16 in C++ RAII memory to UTF-8 in manually-managed C memory\n"
afterCall += "\t\tQByteArray b = ret[i].toUtf8();\n"
afterCall += "\t\t__out[i] = static_cast<char*>(malloc(b.length()));\n"
afterCall += "\t\tmemcpy(__out[i], b.data(), b.length());\n"
afterCall += "\t\t__out_Lengths[i] = b.length();\n"
afterCall += "\t}\n"
afterCall += "\t*_out = __out;\n"
afterCall += "\t*_out_Lengths = __out_Lengths;\n"
afterCall += "\t*_out_len = ret.length();\n"
} else if !t.QtClassType() || (t.QtClassType() && t.Pointer) { // QList<int>, QList<QFoo*>
shouldReturn = m.ReturnType.RenderTypeQtCpp() + " ret = "
afterCall += "\t// Convert QList<> from C++ memory to manually-managed C memory\n"
afterCall += "\t" + t.RenderTypeCabi() + "* __out = static_cast<" + t.RenderTypeCabi() + "*>(malloc(sizeof(" + t.RenderTypeCabi() + ") * ret.length()));\n"
afterCall += "\tfor (size_t i = 0, e = ret.length(); i < e; ++i) {\n"
if t.Const {
nonConst := t // copy
nonConst.Const = false
afterCall += "\t\t__out[i] = const_cast<" + t.RenderTypeCabi() + ">(ret[i]);\n"
} else {
afterCall += "\t\t__out[i] = ret[i];\n"
}
afterCall += "\t}\n"
afterCall += "\t*_out = __out;\n"
afterCall += "\t*_out_len = ret.length();\n"
} else { // QList<QFoo>
shouldReturn = m.ReturnType.RenderTypeQtCpp() + " ret = "
afterCall += "\t// Convert QList<> from C++ memory to manually-managed C memory of copy-constructed pointers\n"
afterCall += "\t" + t.RenderTypeCabi() + "** __out = static_cast<" + t.RenderTypeCabi() + "**>(malloc(sizeof(" + t.RenderTypeCabi() + "**) * ret.length()));\n"
afterCall += "\tfor (size_t i = 0, e = ret.length(); i < e; ++i) {\n"
afterCall += "\t\t__out[i] = new " + t.ParameterType + "(ret[i]);\n"
afterCall += "\t}\n"
afterCall += "\t*_out = __out;\n"
afterCall += "\t*_out_len = ret.length();\n"
}
} else if m.ReturnType.QtClassType() && m.ReturnType.ByRef {
// It's a pointer in disguise, just needs one cast
shouldReturn = m.ReturnType.RenderTypeQtCpp() + " ret = "
afterCall += "\t// Cast returned reference into pointer\n"
if m.ReturnType.Const {
nonConst := m.ReturnType // copy
nonConst.Const = false
nonConst.ByRef = false
nonConst.Pointer = true
nonConst.PointerCount = 1
afterCall += "\treturn const_cast<" + nonConst.RenderTypeQtCpp() + ">(&ret);\n"
} else {
afterCall += "\treturn &ret;\n"
}
} else if m.ReturnType.QtClassType() && !m.ReturnType.Pointer {
shouldReturn = m.ReturnType.ParameterType + " ret = "
afterCall = "\t// Copy-construct value returned type into heap-allocated copy\n"
afterCall += "\treturn static_cast<" + m.ReturnType.ParameterType + "*>(new " + m.ReturnType.ParameterType + "(ret));\n"
} else if m.ReturnType.Const {
shouldReturn += "(" + emitReturnTypeCabi(m.ReturnType) + ") "
} else if m.ReturnType.IsFlagType() {
// Needs an explicit int cast
shouldReturn = m.ReturnType.RenderTypeQtCpp() + " ret = "
afterCall += "\treturn static_cast<int>(ret);\n"
} else if m.ReturnType.IsEnum() {
// Needs an explicit uintptr cast
shouldReturn = m.ReturnType.RenderTypeQtCpp() + " ret = "
afterCall += "\treturn static_cast<uintptr_t>(ret);\n"
}
preamble, forwarding := emitParametersCABI2CppForwarding(m.Parameters)
nativeMethodName := m.MethodName
if m.OverrideMethodName != "" {
nativeMethodName = m.OverrideMethodName
}
callTarget := "self->"
if m.IsStatic {
callTarget = c.ClassName + "::"
} else if m.IsConst {
callTarget = "const_cast<const " + c.ClassName + "*>(self)->"
}
if m.LinuxOnly {
ret.WriteString(fmt.Sprintf(
"%s %s_%s(%s) {\n"+
"#ifdef Q_OS_LINUX\n"+
"%s"+
"\t%s%s%s(%s);\n"+
"%s"+
"#else\n"+
"\t%s _ret_invalidOS;\n"+
"\treturn _ret_invalidOS;\n"+
"#endif\n"+
"}\n"+
"\n",
emitReturnTypeCabi(m.ReturnType), cClassName, m.SafeMethodName(), emitParametersCabi(m, cClassName+"*"),
preamble,
shouldReturn, callTarget, nativeMethodName, forwarding,
afterCall,
emitReturnTypeCabi(m.ReturnType),
))
} else {
ret.WriteString(fmt.Sprintf(
"%s %s_%s(%s) {\n"+
"%s"+
"\t%s%s%s(%s);\n"+
"%s"+
"}\n"+
"\n",
emitReturnTypeCabi(m.ReturnType), cClassName, m.SafeMethodName(), emitParametersCabi(m, cClassName+"*"),
preamble,
shouldReturn, callTarget, nativeMethodName, forwarding,
afterCall,
))
}
if m.IsSignal && !m.HasHiddenParams {
exactSignal := `static_cast<void (` + c.ClassName + `::*)(` + emitParameterTypesCpp(m) + `)>(&` + c.ClassName + `::` + nativeMethodName + `)`
ret.WriteString(
`void ` + cClassName + `_connect_` + m.SafeMethodName() + `(` + cClassName + `* self, void* slot) {` + "\n" +
"\t" + c.ClassName + `::connect(self, ` + exactSignal + `, self, [=](` + emitParametersCpp(m) + `) {` + "\n" +
"\t\t" + `miqt_exec_callback(slot, 0, nullptr);` + "\n" +
"\t});\n" +
"}\n" +
"\n",
)
}
}
// Delete
if c.CanDelete {
ret.WriteString(fmt.Sprintf(
"void %s_Delete(%s* self) {\n"+
"\tdelete self;\n"+
"}\n"+
"\n",
cClassName, cClassName,
))
}
}
return ret.String(), nil
}
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