// Copyright 2011 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 is called cgo_unix.go, but to allow syscalls-to-libc-based
// implementations to share the code, it does not use cgo directly.
// Instead of C.foo it uses _C_foo, which is defined in either
// cgo_unix_cgo.go or cgo_unix_syscall.go

//go:build !netgo && ((cgo && unix) || darwin)

package net

import (
	"context"
	"errors"
	"net/netip"
	"syscall"
	"unsafe"

	"golang.org/x/net/dns/dnsmessage"
)

// cgoAvailable set to true to indicate that the cgo resolver
// is available on this system.
const cgoAvailable = true

// An addrinfoErrno represents a getaddrinfo, getnameinfo-specific
// error number. It's a signed number and a zero value is a non-error
// by convention.
type addrinfoErrno int

func (eai addrinfoErrno) Error() string   { return _C_gai_strerror(_C_int(eai)) }
func (eai addrinfoErrno) Temporary() bool { return eai == _C_EAI_AGAIN }
func (eai addrinfoErrno) Timeout() bool   { return false }

// isAddrinfoErrno is just for testing purposes.
func (eai addrinfoErrno) isAddrinfoErrno() {}

// doBlockingWithCtx executes a blocking function in a separate goroutine when the provided
// context is cancellable. It is intended for use with calls that don't support context
// cancellation (cgo, syscalls). blocking func may still be running after this function finishes.
func doBlockingWithCtx[T any](ctx context.Context, blocking func() (T, error)) (T, error) {
	if ctx.Done() == nil {
		return blocking()
	}

	type result struct {
		res T
		err error
	}

	res := make(chan result, 1)
	go func() {
		var r result
		r.res, r.err = blocking()
		res <- r
	}()

	select {
	case r := <-res:
		return r.res, r.err
	case <-ctx.Done():
		var zero T
		return zero, mapErr(ctx.Err())
	}
}

func cgoLookupHost(ctx context.Context, name string) (hosts []string, err error) {
	addrs, err := cgoLookupIP(ctx, "ip", name)
	if err != nil {
		return nil, err
	}
	for _, addr := range addrs {
		hosts = append(hosts, addr.String())
	}
	return hosts, nil
}

func cgoLookupPort(ctx context.Context, network, service string) (port int, err error) {
	var hints _C_struct_addrinfo
	switch network {
	case "ip": // no hints
	case "tcp", "tcp4", "tcp6":
		*_C_ai_socktype(&hints) = _C_SOCK_STREAM
		*_C_ai_protocol(&hints) = _C_IPPROTO_TCP
	case "udp", "udp4", "udp6":
		*_C_ai_socktype(&hints) = _C_SOCK_DGRAM
		*_C_ai_protocol(&hints) = _C_IPPROTO_UDP
	default:
		return 0, &DNSError{Err: "unknown network", Name: network + "/" + service}
	}
	switch ipVersion(network) {
	case '4':
		*_C_ai_family(&hints) = _C_AF_INET
	case '6':
		*_C_ai_family(&hints) = _C_AF_INET6
	}

	return doBlockingWithCtx(ctx, func() (int, error) {
		return cgoLookupServicePort(&hints, network, service)
	})
}

func cgoLookupServicePort(hints *_C_struct_addrinfo, network, service string) (port int, err error) {
	cservice, err := syscall.ByteSliceFromString(service)
	if err != nil {
		return 0, &DNSError{Err: err.Error(), Name: network + "/" + service}
	}
	// Lowercase the C service name.
	for i, b := range cservice[:len(service)] {
		cservice[i] = lowerASCII(b)
	}
	var res *_C_struct_addrinfo
	gerrno, err := _C_getaddrinfo(nil, (*_C_char)(unsafe.Pointer(&cservice[0])), hints, &res)
	if gerrno != 0 {
		isTemporary := false
		switch gerrno {
		case _C_EAI_SYSTEM:
			if err == nil { // see golang.org/issue/6232
				err = syscall.EMFILE
			}
		case _C_EAI_SERVICE, _C_EAI_NONAME: // Darwin returns EAI_NONAME.
			return 0, &DNSError{Err: "unknown port", Name: network + "/" + service, IsNotFound: true}
		default:
			err = addrinfoErrno(gerrno)
			isTemporary = addrinfoErrno(gerrno).Temporary()
		}
		return 0, &DNSError{Err: err.Error(), Name: network + "/" + service, IsTemporary: isTemporary}
	}
	defer _C_freeaddrinfo(res)

	for r := res; r != nil; r = *_C_ai_next(r) {
		switch *_C_ai_family(r) {
		case _C_AF_INET:
			sa := (*syscall.RawSockaddrInet4)(unsafe.Pointer(*_C_ai_addr(r)))
			p := (*[2]byte)(unsafe.Pointer(&sa.Port))
			return int(p[0])<<8 | int(p[1]), nil
		case _C_AF_INET6:
			sa := (*syscall.RawSockaddrInet6)(unsafe.Pointer(*_C_ai_addr(r)))
			p := (*[2]byte)(unsafe.Pointer(&sa.Port))
			return int(p[0])<<8 | int(p[1]), nil
		}
	}
	return 0, &DNSError{Err: "unknown port", Name: network + "/" + service, IsNotFound: true}
}

func cgoLookupHostIP(network, name string) (addrs []IPAddr, err error) {
	acquireThread()
	defer releaseThread()

	var hints _C_struct_addrinfo
	*_C_ai_flags(&hints) = cgoAddrInfoFlags
	*_C_ai_socktype(&hints) = _C_SOCK_STREAM
	*_C_ai_family(&hints) = _C_AF_UNSPEC
	switch ipVersion(network) {
	case '4':
		*_C_ai_family(&hints) = _C_AF_INET
	case '6':
		*_C_ai_family(&hints) = _C_AF_INET6
	}

	h, err := syscall.BytePtrFromString(name)
	if err != nil {
		return nil, &DNSError{Err: err.Error(), Name: name}
	}
	var res *_C_struct_addrinfo
	gerrno, err := _C_getaddrinfo((*_C_char)(unsafe.Pointer(h)), nil, &hints, &res)
	if gerrno != 0 {
		isErrorNoSuchHost := false
		isTemporary := false
		switch gerrno {
		case _C_EAI_SYSTEM:
			if err == nil {
				// err should not be nil, but sometimes getaddrinfo returns
				// gerrno == _C_EAI_SYSTEM with err == nil on Linux.
				// The report claims that it happens when we have too many
				// open files, so use syscall.EMFILE (too many open files in system).
				// Most system calls would return ENFILE (too many open files),
				// so at the least EMFILE should be easy to recognize if this
				// comes up again. golang.org/issue/6232.
				err = syscall.EMFILE
			}
		case _C_EAI_NONAME, _C_EAI_NODATA:
			err = errNoSuchHost
			isErrorNoSuchHost = true
		default:
			err = addrinfoErrno(gerrno)
			isTemporary = addrinfoErrno(gerrno).Temporary()
		}

		return nil, &DNSError{Err: err.Error(), Name: name, IsNotFound: isErrorNoSuchHost, IsTemporary: isTemporary}
	}
	defer _C_freeaddrinfo(res)

	for r := res; r != nil; r = *_C_ai_next(r) {
		// We only asked for SOCK_STREAM, but check anyhow.
		if *_C_ai_socktype(r) != _C_SOCK_STREAM {
			continue
		}
		switch *_C_ai_family(r) {
		case _C_AF_INET:
			sa := (*syscall.RawSockaddrInet4)(unsafe.Pointer(*_C_ai_addr(r)))
			addr := IPAddr{IP: copyIP(sa.Addr[:])}
			addrs = append(addrs, addr)
		case _C_AF_INET6:
			sa := (*syscall.RawSockaddrInet6)(unsafe.Pointer(*_C_ai_addr(r)))
			addr := IPAddr{IP: copyIP(sa.Addr[:]), Zone: zoneCache.name(int(sa.Scope_id))}
			addrs = append(addrs, addr)
		}
	}
	return addrs, nil
}

func cgoLookupIP(ctx context.Context, network, name string) (addrs []IPAddr, err error) {
	return doBlockingWithCtx(ctx, func() ([]IPAddr, error) {
		return cgoLookupHostIP(network, name)
	})
}

// These are roughly enough for the following:
//
//	 Source		Encoding			Maximum length of single name entry
//	 Unicast DNS		ASCII or			<=253 + a NUL terminator
//				Unicode in RFC 5892		252 * total number of labels + delimiters + a NUL terminator
//	 Multicast DNS	UTF-8 in RFC 5198 or		<=253 + a NUL terminator
//				the same as unicast DNS ASCII	<=253 + a NUL terminator
//	 Local database	various				depends on implementation
const (
	nameinfoLen    = 64
	maxNameinfoLen = 4096
)

func cgoLookupPTR(ctx context.Context, addr string) (names []string, err error) {
	ip, err := netip.ParseAddr(addr)
	if err != nil {
		return nil, &DNSError{Err: "invalid address", Name: addr}
	}
	sa, salen := cgoSockaddr(IP(ip.AsSlice()), ip.Zone())
	if sa == nil {
		return nil, &DNSError{Err: "invalid address " + ip.String(), Name: addr}
	}

	return doBlockingWithCtx(ctx, func() ([]string, error) {
		return cgoLookupAddrPTR(addr, sa, salen)
	})
}

func cgoLookupAddrPTR(addr string, sa *_C_struct_sockaddr, salen _C_socklen_t) (names []string, err error) {
	acquireThread()
	defer releaseThread()

	var gerrno int
	var b []byte
	for l := nameinfoLen; l <= maxNameinfoLen; l *= 2 {
		b = make([]byte, l)
		gerrno, err = cgoNameinfoPTR(b, sa, salen)
		if gerrno == 0 || gerrno != _C_EAI_OVERFLOW {
			break
		}
	}
	if gerrno != 0 {
		isErrorNoSuchHost := false
		isTemporary := false
		switch gerrno {
		case _C_EAI_SYSTEM:
			if err == nil { // see golang.org/issue/6232
				err = syscall.EMFILE
			}
		case _C_EAI_NONAME:
			err = errNoSuchHost
			isErrorNoSuchHost = true
		default:
			err = addrinfoErrno(gerrno)
			isTemporary = addrinfoErrno(gerrno).Temporary()
		}
		return nil, &DNSError{Err: err.Error(), Name: addr, IsTemporary: isTemporary, IsNotFound: isErrorNoSuchHost}
	}
	for i := 0; i < len(b); i++ {
		if b[i] == 0 {
			b = b[:i]
			break
		}
	}
	return []string{absDomainName(string(b))}, nil
}

func cgoSockaddr(ip IP, zone string) (*_C_struct_sockaddr, _C_socklen_t) {
	if ip4 := ip.To4(); ip4 != nil {
		return cgoSockaddrInet4(ip4), _C_socklen_t(syscall.SizeofSockaddrInet4)
	}
	if ip6 := ip.To16(); ip6 != nil {
		return cgoSockaddrInet6(ip6, zoneCache.index(zone)), _C_socklen_t(syscall.SizeofSockaddrInet6)
	}
	return nil, 0
}

func cgoLookupCNAME(ctx context.Context, name string) (cname string, err error, completed bool) {
	resources, err := resSearch(ctx, name, int(dnsmessage.TypeCNAME), int(dnsmessage.ClassINET))
	if err != nil {
		return
	}
	cname, err = parseCNAMEFromResources(resources)
	if err != nil {
		return "", err, false
	}
	return cname, nil, true
}

// resSearch will make a call to the 'res_nsearch' routine in the C library
// and parse the output as a slice of DNS resources.
func resSearch(ctx context.Context, hostname string, rtype, class int) ([]dnsmessage.Resource, error) {
	return doBlockingWithCtx(ctx, func() ([]dnsmessage.Resource, error) {
		return cgoResSearch(hostname, rtype, class)
	})
}

func cgoResSearch(hostname string, rtype, class int) ([]dnsmessage.Resource, error) {
	acquireThread()
	defer releaseThread()

	resStateSize := unsafe.Sizeof(_C_struct___res_state{})
	var state *_C_struct___res_state
	if resStateSize > 0 {
		mem := _C_malloc(resStateSize)
		defer _C_free(mem)
		memSlice := unsafe.Slice((*byte)(mem), resStateSize)
		clear(memSlice)
		state = (*_C_struct___res_state)(unsafe.Pointer(&memSlice[0]))
	}
	if err := _C_res_ninit(state); err != nil {
		return nil, errors.New("res_ninit failure: " + err.Error())
	}
	defer _C_res_nclose(state)

	// Some res_nsearch implementations (like macOS) do not set errno.
	// They set h_errno, which is not per-thread and useless to us.
	// res_nsearch returns the size of the DNS response packet.
	// But if the DNS response packet contains failure-like response codes,
	// res_search returns -1 even though it has copied the packet into buf,
	// giving us no way to find out how big the packet is.
	// For now, we are willing to take res_search's word that there's nothing
	// useful in the response, even though there *is* a response.
	bufSize := maxDNSPacketSize
	buf := (*_C_uchar)(_C_malloc(uintptr(bufSize)))
	defer _C_free(unsafe.Pointer(buf))

	s, err := syscall.BytePtrFromString(hostname)
	if err != nil {
		return nil, err
	}

	var size int
	for {
		size, _ = _C_res_nsearch(state, (*_C_char)(unsafe.Pointer(s)), class, rtype, buf, bufSize)
		if size <= 0 || size > 0xffff {
			return nil, errors.New("res_nsearch failure")
		}
		if size <= bufSize {
			break
		}

		// Allocate a bigger buffer to fit the entire msg.
		_C_free(unsafe.Pointer(buf))
		bufSize = size
		buf = (*_C_uchar)(_C_malloc(uintptr(bufSize)))
	}

	var p dnsmessage.Parser
	if _, err := p.Start(unsafe.Slice((*byte)(unsafe.Pointer(buf)), size)); err != nil {
		return nil, err
	}
	p.SkipAllQuestions()
	resources, err := p.AllAnswers()
	if err != nil {
		return nil, err
	}
	return resources, nil
}