/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "WifiUtils.h" #include #include #include #include "prinit.h" #include "js/CharacterEncoding.h" #include "mozilla/dom/network/NetUtils.h" using namespace mozilla::dom; #define BUFFER_SIZE 4096 #define COMMAND_SIZE 256 #define PROPERTY_VALUE_MAX 80 // Intentionally not trying to dlclose() this handle. That's playing // Russian roulette with security bugs. static void* sWifiLib; static PRCallOnceType sInitWifiLib; static PRStatus InitWifiLib() { sWifiLib = dlopen("/system/lib/libhardware_legacy.so", RTLD_LAZY); // We might fail to open the hardware lib. That's OK. return PR_SUCCESS; } static void* GetSharedLibrary() { PR_CallOnce(&sInitWifiLib, InitWifiLib); return sWifiLib; } static bool GetWifiP2pSupported() { char propP2pSupported[PROPERTY_VALUE_MAX]; property_get("ro.moz.wifi.p2p_supported", propP2pSupported, "0"); return (0 == strcmp(propP2pSupported, "1")); } int hex2num(char c) { if (c >= '0' && c <= '9') return c - '0'; if (c >= 'a' && c <= 'f') return c - 'a' + 10; if (c >= 'A' && c <= 'F') return c - 'A' + 10; return -1; } int hex2byte(const char* hex) { int a, b; a = hex2num(*hex++); if (a < 0) return -1; b = hex2num(*hex++); if (b < 0) return -1; return (a << 4) | b; } // This function is equivalent to printf_decode() at src/utils/common.c in // the supplicant. uint32_t convertToBytes(char* buf, uint32_t maxlen, const char* str) { const char *pos = str; uint32_t len = 0; int val; while (*pos) { if (len == maxlen) break; switch (*pos) { case '\\': pos++; switch (*pos) { case '\\': buf[len++] = '\\'; pos++; break; case '"': buf[len++] = '"'; pos++; break; case 'n': buf[len++] = '\n'; pos++; break; case 'r': buf[len++] = '\r'; pos++; break; case 't': buf[len++] = '\t'; pos++; break; case 'e': buf[len++] = '\e'; pos++; break; case 'x': pos++; val = hex2byte(pos); if (val < 0) { val = hex2num(*pos); if (val < 0) break; buf[len++] = val; pos++; } else { buf[len++] = val; pos += 2; } break; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': val = *pos++ - '0'; if (*pos >= '0' && *pos <= '7') val = val * 8 + (*pos++ - '0'); if (*pos >= '0' && *pos <= '7') val = val * 8 + (*pos++ - '0'); buf[len++] = val; break; default: break; } break; default: buf[len++] = *pos++; break; } } return len; } // This is the same algorithm as in InflateUTF8StringToBuffer with Copy and // while ignoring invalids. // https://mxr.mozilla.org/mozilla-central/source/js/src/vm/CharacterEncoding.cpp#231 static const uint32_t REPLACE_UTF8 = 0xFFFD; void LossyConvertUTF8toUTF16(const char* aInput, uint32_t aLength, nsAString& aOut) { JS::UTF8Chars src(aInput, aLength); char16_t dst[aLength]; // Allocating for worst case. // First, count how many jschars need to be in the inflated string. // |i| is the index into |src|, and |j| is the the index into |dst|. size_t srclen = src.length(); uint32_t j = 0; for (uint32_t i = 0; i < srclen; i++, j++) { uint32_t v = uint32_t(src[i]); if (!(v & 0x80)) { // ASCII code unit. Simple copy. dst[j] = char16_t(v); } else { // Non-ASCII code unit. Determine its length in bytes (n). uint32_t n = 1; while (v & (0x80 >> n)) n++; #define INVALID(report, arg, n2) \ do { \ n = n2; \ goto invalidMultiByteCodeUnit; \ } while (0) // Check the leading byte. if (n < 2 || n > 4) INVALID(ReportInvalidCharacter, i, 1); // Check that |src| is large enough to hold an n-byte code unit. if (i + n > srclen) INVALID(ReportBufferTooSmall, /* dummy = */ 0, 1); // Check the second byte. From Unicode Standard v6.2, Table 3-7 // Well-Formed UTF-8 Byte Sequences. if ((v == 0xE0 && ((uint8_t)src[i + 1] & 0xE0) != 0xA0) || // E0 A0~BF (v == 0xED && ((uint8_t)src[i + 1] & 0xE0) != 0x80) || // ED 80~9F (v == 0xF0 && ((uint8_t)src[i + 1] & 0xF0) == 0x80) || // F0 90~BF (v == 0xF4 && ((uint8_t)src[i + 1] & 0xF0) != 0x80)) // F4 80~8F { INVALID(ReportInvalidCharacter, i, 1); } // Check the continuation bytes. for (uint32_t m = 1; m < n; m++) if ((src[i + m] & 0xC0) != 0x80) INVALID(ReportInvalidCharacter, i, m); // Determine the code unit's length in jschars and act accordingly. v = JS::Utf8ToOneUcs4Char((uint8_t *)&src[i], n); if (v < 0x10000) { // The n-byte UTF8 code unit will fit in a single jschar. dst[j] = jschar(v); } else { v -= 0x10000; if (v <= 0xFFFFF) { // The n-byte UTF8 code unit will fit in two jschars. dst[j] = jschar((v >> 10) + 0xD800); j++; dst[j] = jschar((v & 0x3FF) + 0xDC00); } else { // The n-byte UTF8 code unit won't fit in two jschars. INVALID(ReportTooBigCharacter, v, 1); } } invalidMultiByteCodeUnit: // Move i to the last byte of the multi-byte code unit; the loop // header will do the final i++ to move to the start of the next // code unit. i += n - 1; } } dst[j] = 0; aOut = dst; } // Helper to check we have loaded the hardware shared library. #define CHECK_HWLIB(ret) \ void* hwLib = GetSharedLibrary(); \ if (!hwLib) { \ NS_WARNING("No /system/lib/libhardware_legacy.so"); \ return ret; \ } #define DEFAULT_IMPL(name, ret, args...) \ DEFINE_DLFUNC(name, ret, args...) \ ret do_##name(args) { \ USE_DLFUNC(name) \ return name(args); \ } // ICS implementation. class ICSWpaSupplicantImpl : public WpaSupplicantImpl { public: DEFAULT_IMPL(wifi_load_driver, int32_t, ) DEFAULT_IMPL(wifi_unload_driver, int32_t, ) DEFINE_DLFUNC(wifi_wait_for_event, int32_t, char*, size_t) int32_t do_wifi_wait_for_event(const char *iface, char *buf, size_t len) { USE_DLFUNC(wifi_wait_for_event) return wifi_wait_for_event(buf, len); } DEFINE_DLFUNC(wifi_command, int32_t, const char*, char*, size_t*) int32_t do_wifi_command(const char* iface, const char* cmd, char* buf, size_t* len) { USE_DLFUNC(wifi_command) return wifi_command(cmd, buf, len); } DEFINE_DLFUNC(wifi_start_supplicant, int32_t, ) int32_t do_wifi_start_supplicant(int32_t) { USE_DLFUNC(wifi_start_supplicant) return wifi_start_supplicant(); } DEFINE_DLFUNC(wifi_stop_supplicant, int32_t) int32_t do_wifi_stop_supplicant(int32_t) { USE_DLFUNC(wifi_stop_supplicant) return wifi_stop_supplicant(); } DEFINE_DLFUNC(wifi_connect_to_supplicant, int32_t, ) int32_t do_wifi_connect_to_supplicant(const char* iface) { USE_DLFUNC(wifi_connect_to_supplicant) return wifi_connect_to_supplicant(); } DEFINE_DLFUNC(wifi_close_supplicant_connection, void, ) void do_wifi_close_supplicant_connection(const char* iface) { USE_DLFUNC(wifi_close_supplicant_connection) return wifi_close_supplicant_connection(); } }; // JB implementation. // We only redefine the methods that have a different signature than on ICS. class JBWpaSupplicantImpl : public ICSWpaSupplicantImpl { public: DEFINE_DLFUNC(wifi_wait_for_event, int32_t, const char*, char*, size_t) int32_t do_wifi_wait_for_event(const char* iface, char* buf, size_t len) { USE_DLFUNC(wifi_wait_for_event) return wifi_wait_for_event(iface, buf, len); } DEFINE_DLFUNC(wifi_command, int32_t, const char*, const char*, char*, size_t*) int32_t do_wifi_command(const char* iface, const char* cmd, char* buf, size_t* len) { USE_DLFUNC(wifi_command) return wifi_command(iface, cmd, buf, len); } DEFINE_DLFUNC(wifi_start_supplicant, int32_t, int32_t) int32_t do_wifi_start_supplicant(int32_t arg) { USE_DLFUNC(wifi_start_supplicant) return wifi_start_supplicant(arg); } DEFINE_DLFUNC(wifi_stop_supplicant, int32_t, int32_t) int32_t do_wifi_stop_supplicant(int32_t arg) { USE_DLFUNC(wifi_stop_supplicant) return wifi_stop_supplicant(arg); } DEFINE_DLFUNC(wifi_connect_to_supplicant, int32_t, const char*) int32_t do_wifi_connect_to_supplicant(const char* iface) { USE_DLFUNC(wifi_connect_to_supplicant) return wifi_connect_to_supplicant(iface); } DEFINE_DLFUNC(wifi_close_supplicant_connection, void, const char*) void do_wifi_close_supplicant_connection(const char* iface) { USE_DLFUNC(wifi_close_supplicant_connection) wifi_close_supplicant_connection(iface); } }; // KK implementation. // We only redefine the methods that have a different signature than on ICS. class KKWpaSupplicantImpl : public ICSWpaSupplicantImpl { public: DEFINE_DLFUNC(wifi_start_supplicant, int32_t, int32_t) int32_t do_wifi_start_supplicant(int32_t arg) { USE_DLFUNC(wifi_start_supplicant) return wifi_start_supplicant(arg); } DEFINE_DLFUNC(wifi_stop_supplicant, int32_t, int32_t) int32_t do_wifi_stop_supplicant(int32_t arg) { USE_DLFUNC(wifi_stop_supplicant) return wifi_stop_supplicant(arg); } DEFINE_DLFUNC(wifi_command, int32_t, const char*, char*, size_t*) int32_t do_wifi_command(const char* iface, const char* cmd, char* buf, size_t* len) { char command[COMMAND_SIZE]; if (!strcmp(iface, "p2p0")) { // Commands for p2p0 interface don't need prefix snprintf(command, COMMAND_SIZE, "%s", cmd); } else { snprintf(command, COMMAND_SIZE, "IFNAME=%s %s", iface, cmd); } USE_DLFUNC(wifi_command) return wifi_command(command, buf, len); } }; // Concrete class to use to access the wpa supplicant. WpaSupplicant::WpaSupplicant() { if (NetUtils::SdkVersion() < 16) { mImpl = new ICSWpaSupplicantImpl(); } else if (NetUtils::SdkVersion() < 19) { mImpl = new JBWpaSupplicantImpl(); } else { mImpl = new KKWpaSupplicantImpl(); } mNetUtils = new NetUtils(); mWifiHotspotUtils = new WifiHotspotUtils(); }; void WpaSupplicant::WaitForEvent(nsAString& aEvent, const nsCString& aInterface) { CHECK_HWLIB() char buffer[BUFFER_SIZE]; int32_t ret = mImpl->do_wifi_wait_for_event(aInterface.get(), buffer, BUFFER_SIZE); CheckBuffer(buffer, ret, aEvent); } #define GET_CHAR(prop) NS_ConvertUTF16toUTF8(aOptions.prop).get() /** * Make a subnet mask. */ uint32_t WpaSupplicant::MakeMask(uint32_t len) { uint32_t mask = 0; for (uint32_t i = 0; i < len; ++i) { mask |= (0x80000000 >> i); } return ntohl(mask); } bool WpaSupplicant::ExecuteCommand(CommandOptions aOptions, WifiResultOptions& aResult, const nsCString& aInterface) { CHECK_HWLIB(false) if (!mNetUtils->GetSharedLibrary()) { return false; } if (!mWifiHotspotUtils->GetSharedLibrary()) { return false; } // Always correlate the opaque ids. aResult.mId = aOptions.mId; if (aOptions.mCmd.EqualsLiteral("command")) { size_t len = BUFFER_SIZE - 1; char buffer[BUFFER_SIZE]; NS_ConvertUTF16toUTF8 request(aOptions.mRequest); aResult.mStatus = mImpl->do_wifi_command(aInterface.get(), request.get(), buffer, &len); nsString value; if (aResult.mStatus == 0) { if (buffer[len - 1] == '\n') { // remove trailing new lines. len--; } buffer[len] = '\0'; CheckBuffer(buffer, len, value); } aResult.mReply = value; } else if (aOptions.mCmd.EqualsLiteral("close_supplicant_connection")) { mImpl->do_wifi_close_supplicant_connection(aInterface.get()); } else if (aOptions.mCmd.EqualsLiteral("load_driver")) { aResult.mStatus = mImpl->do_wifi_load_driver(); } else if (aOptions.mCmd.EqualsLiteral("unload_driver")) { aResult.mStatus = mImpl->do_wifi_unload_driver(); } else if (aOptions.mCmd.EqualsLiteral("start_supplicant")) { aResult.mStatus = mImpl->do_wifi_start_supplicant(GetWifiP2pSupported() ? 1 : 0); } else if (aOptions.mCmd.EqualsLiteral("stop_supplicant")) { aResult.mStatus = mImpl->do_wifi_stop_supplicant(0); } else if (aOptions.mCmd.EqualsLiteral("connect_to_supplicant")) { aResult.mStatus = mImpl->do_wifi_connect_to_supplicant(aInterface.get()); } else if (aOptions.mCmd.EqualsLiteral("ifc_enable")) { aResult.mStatus = mNetUtils->do_ifc_enable(GET_CHAR(mIfname)); } else if (aOptions.mCmd.EqualsLiteral("ifc_disable")) { aResult.mStatus = mNetUtils->do_ifc_disable(GET_CHAR(mIfname)); } else if (aOptions.mCmd.EqualsLiteral("ifc_configure")) { aResult.mStatus = mNetUtils->do_ifc_configure( GET_CHAR(mIfname), aOptions.mIpaddr, aOptions.mMask, aOptions.mGateway, aOptions.mDns1, aOptions.mDns2 ); } else if (aOptions.mCmd.EqualsLiteral("ifc_reset_connections")) { aResult.mStatus = mNetUtils->do_ifc_reset_connections( GET_CHAR(mIfname), RESET_ALL_ADDRESSES ); } else if (aOptions.mCmd.EqualsLiteral("dhcp_stop")) { aResult.mStatus = mNetUtils->do_dhcp_stop(GET_CHAR(mIfname)); } else if (aOptions.mCmd.EqualsLiteral("dhcp_do_request")) { char ipaddr[PROPERTY_VALUE_MAX]; char gateway[PROPERTY_VALUE_MAX]; uint32_t prefixLength; char dns1[PROPERTY_VALUE_MAX]; char dns2[PROPERTY_VALUE_MAX]; char server[PROPERTY_VALUE_MAX]; uint32_t lease; char vendorinfo[PROPERTY_VALUE_MAX]; aResult.mStatus = mNetUtils->do_dhcp_do_request(GET_CHAR(mIfname), ipaddr, gateway, &prefixLength, dns1, dns2, server, &lease, vendorinfo); if (aResult.mStatus == -1) { // Early return since we failed. return true; } aResult.mIpaddr_str = NS_ConvertUTF8toUTF16(ipaddr); aResult.mGateway_str = NS_ConvertUTF8toUTF16(gateway); aResult.mDns1_str = NS_ConvertUTF8toUTF16(dns1); aResult.mDns2_str = NS_ConvertUTF8toUTF16(dns2); aResult.mServer_str = NS_ConvertUTF8toUTF16(server); aResult.mVendor_str = NS_ConvertUTF8toUTF16(vendorinfo); aResult.mLease = lease; aResult.mMask = MakeMask(prefixLength); uint32_t inet4; // only support IPv4 for now. #define INET_PTON(var, field) \ PR_BEGIN_MACRO \ inet_pton(AF_INET, var, &inet4); \ aResult.field = inet4; \ PR_END_MACRO INET_PTON(ipaddr, mIpaddr); INET_PTON(gateway, mGateway); if (dns1[0] != '\0') { INET_PTON(dns1, mDns1); } if (dns2[0] != '\0') { INET_PTON(dns2, mDns2); } INET_PTON(server, mServer); //aResult.mask_str = netHelpers.ipToString(obj.mask); char inet_str[64]; if (inet_ntop(AF_INET, &aResult.mMask, inet_str, sizeof(inet_str))) { aResult.mMask_str = NS_ConvertUTF8toUTF16(inet_str); } } else if (aOptions.mCmd.EqualsLiteral("hostapd_command")) { size_t len = BUFFER_SIZE - 1; char buffer[BUFFER_SIZE]; NS_ConvertUTF16toUTF8 request(aOptions.mRequest); aResult.mStatus = mWifiHotspotUtils->do_wifi_hostapd_command(request.get(), buffer, &len); nsString value; if (aResult.mStatus == 0) { if (buffer[len - 1] == '\n') { // remove trailing new lines. len--; } buffer[len] = '\0'; CheckBuffer(buffer, len, value); } aResult.mReply = value; } else if (aOptions.mCmd.EqualsLiteral("hostapd_get_stations")) { aResult.mStatus = mWifiHotspotUtils->do_wifi_hostapd_get_stations(); } else if (aOptions.mCmd.EqualsLiteral("connect_to_hostapd")) { aResult.mStatus = mWifiHotspotUtils->do_wifi_connect_to_hostapd(); } else if (aOptions.mCmd.EqualsLiteral("close_hostapd_connection")) { aResult.mStatus = mWifiHotspotUtils->do_wifi_close_hostapd_connection(); } else if (aOptions.mCmd.EqualsLiteral("hostapd_command")) { size_t len = BUFFER_SIZE - 1; char buffer[BUFFER_SIZE]; NS_ConvertUTF16toUTF8 request(aOptions.mRequest); aResult.mStatus = mWifiHotspotUtils->do_wifi_hostapd_command(request.get(), buffer, &len); nsString value; if (aResult.mStatus == 0) { if (buffer[len - 1] == '\n') { // remove trailing new lines. len--; } buffer[len] = '\0'; CheckBuffer(buffer, len, value); } aResult.mReply = value; } else if (aOptions.mCmd.EqualsLiteral("hostapd_get_stations")) { aResult.mStatus = mWifiHotspotUtils->do_wifi_hostapd_get_stations(); } else if (aOptions.mCmd.EqualsLiteral("connect_to_hostapd")) { aResult.mStatus = mWifiHotspotUtils->do_wifi_connect_to_hostapd(); } else if (aOptions.mCmd.EqualsLiteral("close_hostapd_connection")) { aResult.mStatus = mWifiHotspotUtils->do_wifi_close_hostapd_connection(); } else { NS_WARNING("WpaSupplicant::ExecuteCommand : Unknown command"); printf_stderr("WpaSupplicant::ExecuteCommand : Unknown command: %s", NS_ConvertUTF16toUTF8(aOptions.mCmd).get()); return false; } return true; } // Checks the buffer and do the utf processing. void WpaSupplicant::CheckBuffer(char* buffer, int32_t length, nsAString& aEvent) { if (length <= 0 || length >= (BUFFER_SIZE - 1)) { NS_WARNING("WpaSupplicant::CheckBuffer: Invalid buffer length"); return; } if (NetUtils::SdkVersion() < 18) { buffer[length] = 0; LossyConvertUTF8toUTF16(buffer, length, aEvent); return; } // After Android JB4.3, the SSIDs have been converted into printable form. // In most of cases, SSIDs do not use unprintable characters, but IEEE 802.11 // standard does not limit the used character set, so anything could be used // in an SSID. Convert it to raw data form here. char bytesBuffer[BUFFER_SIZE]; uint32_t bytes = convertToBytes(bytesBuffer, length, buffer); if (bytes <= 0 || bytes >= BUFFER_SIZE) { NS_WARNING("WpaSupplicant::CheckBuffer: Invalid bytesbuffer length"); return; } bytesBuffer[bytes] = 0; LossyConvertUTF8toUTF16(bytesBuffer, bytes, aEvent); }