barrier/lib/server/CConfig.cpp
2010-06-20 17:38:51 +00:00

2290 lines
52 KiB
C++

/*
* synergy-plus -- mouse and keyboard sharing utility
* Copyright (C) 2009 The Synergy+ Project
* Copyright (C) 2002 Chris Schoeneman
*
* This package is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* found in the file COPYING that should have accompanied this file.
*
* This package is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "CConfig.h"
#include "CServer.h"
#include "CKeyMap.h"
#include "KeyTypes.h"
#include "XSocket.h"
#include "stdistream.h"
#include "stdostream.h"
#include <cstdlib>
//
// CConfig
//
CConfig::CConfig() : m_hasLockToScreenAction(false)
{
// do nothing
}
CConfig::~CConfig()
{
// do nothing
}
bool
CConfig::addScreen(const CString& name)
{
// alias name must not exist
if (m_nameToCanonicalName.find(name) != m_nameToCanonicalName.end()) {
return false;
}
// add cell
m_map.insert(std::make_pair(name, CCell()));
// add name
m_nameToCanonicalName.insert(std::make_pair(name, name));
return true;
}
bool
CConfig::renameScreen(const CString& oldName,
const CString& newName)
{
// get canonical name and find cell
CString oldCanonical = getCanonicalName(oldName);
CCellMap::iterator index = m_map.find(oldCanonical);
if (index == m_map.end()) {
return false;
}
// accept if names are equal but replace with new name to maintain
// case. otherwise, the new name must not exist.
if (!CStringUtil::CaselessCmp::equal(oldName, newName) &&
m_nameToCanonicalName.find(newName) != m_nameToCanonicalName.end()) {
return false;
}
// update cell
CCell tmpCell = index->second;
m_map.erase(index);
m_map.insert(std::make_pair(newName, tmpCell));
// update name
m_nameToCanonicalName.erase(oldCanonical);
m_nameToCanonicalName.insert(std::make_pair(newName, newName));
// update connections
CName oldNameObj(this, oldName);
for (index = m_map.begin(); index != m_map.end(); ++index) {
index->second.rename(oldNameObj, newName);
}
// update alias targets
if (CStringUtil::CaselessCmp::equal(oldName, oldCanonical)) {
for (CNameMap::iterator iter = m_nameToCanonicalName.begin();
iter != m_nameToCanonicalName.end(); ++iter) {
if (CStringUtil::CaselessCmp::equal(
iter->second, oldCanonical)) {
iter->second = newName;
}
}
}
return true;
}
void
CConfig::removeScreen(const CString& name)
{
// get canonical name and find cell
CString canonical = getCanonicalName(name);
CCellMap::iterator index = m_map.find(canonical);
if (index == m_map.end()) {
return;
}
// remove from map
m_map.erase(index);
// disconnect
CName nameObj(this, name);
for (index = m_map.begin(); index != m_map.end(); ++index) {
index->second.remove(nameObj);
}
// remove aliases (and canonical name)
for (CNameMap::iterator iter = m_nameToCanonicalName.begin();
iter != m_nameToCanonicalName.end(); ) {
if (iter->second == canonical) {
m_nameToCanonicalName.erase(iter++);
}
else {
++index;
}
}
}
void
CConfig::removeAllScreens()
{
m_map.clear();
m_nameToCanonicalName.clear();
}
bool
CConfig::addAlias(const CString& canonical, const CString& alias)
{
// alias name must not exist
if (m_nameToCanonicalName.find(alias) != m_nameToCanonicalName.end()) {
return false;
}
// canonical name must be known
if (m_map.find(canonical) == m_map.end()) {
return false;
}
// insert alias
m_nameToCanonicalName.insert(std::make_pair(alias, canonical));
return true;
}
bool
CConfig::removeAlias(const CString& alias)
{
// must not be a canonical name
if (m_map.find(alias) != m_map.end()) {
return false;
}
// find alias
CNameMap::iterator index = m_nameToCanonicalName.find(alias);
if (index == m_nameToCanonicalName.end()) {
return false;
}
// remove alias
m_nameToCanonicalName.erase(index);
return true;
}
bool
CConfig::removeAliases(const CString& canonical)
{
// must be a canonical name
if (m_map.find(canonical) == m_map.end()) {
return false;
}
// find and removing matching aliases
for (CNameMap::iterator index = m_nameToCanonicalName.begin();
index != m_nameToCanonicalName.end(); ) {
if (index->second == canonical && index->first != canonical) {
m_nameToCanonicalName.erase(index++);
}
else {
++index;
}
}
return true;
}
void
CConfig::removeAllAliases()
{
// remove all names
m_nameToCanonicalName.clear();
// put the canonical names back in
for (CCellMap::iterator index = m_map.begin();
index != m_map.end(); ++index) {
m_nameToCanonicalName.insert(
std::make_pair(index->first, index->first));
}
}
bool
CConfig::connect(const CString& srcName,
EDirection srcSide,
float srcStart, float srcEnd,
const CString& dstName,
float dstStart, float dstEnd)
{
assert(srcSide >= kFirstDirection && srcSide <= kLastDirection);
// find source cell
CCellMap::iterator index = m_map.find(getCanonicalName(srcName));
if (index == m_map.end()) {
return false;
}
// add link
CCellEdge srcEdge(srcSide, CInterval(srcStart, srcEnd));
CCellEdge dstEdge(dstName, srcSide, CInterval(dstStart, dstEnd));
return index->second.add(srcEdge, dstEdge);
}
bool
CConfig::disconnect(const CString& srcName, EDirection srcSide)
{
assert(srcSide >= kFirstDirection && srcSide <= kLastDirection);
// find source cell
CCellMap::iterator index = m_map.find(srcName);
if (index == m_map.end()) {
return false;
}
// disconnect side
index->second.remove(srcSide);
return true;
}
bool
CConfig::disconnect(const CString& srcName, EDirection srcSide, float position)
{
assert(srcSide >= kFirstDirection && srcSide <= kLastDirection);
// find source cell
CCellMap::iterator index = m_map.find(srcName);
if (index == m_map.end()) {
return false;
}
// disconnect side
index->second.remove(srcSide, position);
return true;
}
void
CConfig::setSynergyAddress(const CNetworkAddress& addr)
{
m_synergyAddress = addr;
}
bool
CConfig::addOption(const CString& name, OptionID option, OptionValue value)
{
// find options
CScreenOptions* options = NULL;
if (name.empty()) {
options = &m_globalOptions;
}
else {
CCellMap::iterator index = m_map.find(name);
if (index != m_map.end()) {
options = &index->second.m_options;
}
}
if (options == NULL) {
return false;
}
// add option
options->insert(std::make_pair(option, value));
return true;
}
bool
CConfig::removeOption(const CString& name, OptionID option)
{
// find options
CScreenOptions* options = NULL;
if (name.empty()) {
options = &m_globalOptions;
}
else {
CCellMap::iterator index = m_map.find(name);
if (index != m_map.end()) {
options = &index->second.m_options;
}
}
if (options == NULL) {
return false;
}
// remove option
options->erase(option);
return true;
}
bool
CConfig::removeOptions(const CString& name)
{
// find options
CScreenOptions* options = NULL;
if (name.empty()) {
options = &m_globalOptions;
}
else {
CCellMap::iterator index = m_map.find(name);
if (index != m_map.end()) {
options = &index->second.m_options;
}
}
if (options == NULL) {
return false;
}
// remove options
options->clear();
return true;
}
bool
CConfig::isValidScreenName(const CString& name) const
{
// name is valid if matches validname
// name ::= [_A-Za-z0-9] | [_A-Za-z0-9][-_A-Za-z0-9]*[_A-Za-z0-9]
// domain ::= . name
// validname ::= name domain*
// we also accept names ending in . because many OS X users have
// so misconfigured their systems.
// empty name is invalid
if (name.empty()) {
return false;
}
// check each dot separated part
CString::size_type b = 0;
for (;;) {
// accept trailing .
if (b == name.size()) {
break;
}
// find end of part
CString::size_type e = name.find('.', b);
if (e == CString::npos) {
e = name.size();
}
// part may not be empty
if (e - b < 1) {
return false;
}
// check first and last characters
if (!(isalnum(name[b]) || name[b] == '_') ||
!(isalnum(name[e - 1]) || name[e - 1] == '_')) {
return false;
}
// check interior characters
for (CString::size_type i = b; i < e; ++i) {
if (!isalnum(name[i]) && name[i] != '_' && name[i] != '-') {
return false;
}
}
// next part
if (e == name.size()) {
// no more parts
break;
}
b = e + 1;
}
return true;
}
CConfig::const_iterator
CConfig::begin() const
{
return const_iterator(m_map.begin());
}
CConfig::const_iterator
CConfig::end() const
{
return const_iterator(m_map.end());
}
CConfig::all_const_iterator
CConfig::beginAll() const
{
return m_nameToCanonicalName.begin();
}
CConfig::all_const_iterator
CConfig::endAll() const
{
return m_nameToCanonicalName.end();
}
bool
CConfig::isScreen(const CString& name) const
{
return (m_nameToCanonicalName.count(name) > 0);
}
bool
CConfig::isCanonicalName(const CString& name) const
{
return (!name.empty() &&
CStringUtil::CaselessCmp::equal(getCanonicalName(name), name));
}
CString
CConfig::getCanonicalName(const CString& name) const
{
CNameMap::const_iterator index = m_nameToCanonicalName.find(name);
if (index == m_nameToCanonicalName.end()) {
return CString();
}
else {
return index->second;
}
}
CString
CConfig::getNeighbor(const CString& srcName, EDirection srcSide,
float position, float* positionOut) const
{
assert(srcSide >= kFirstDirection && srcSide <= kLastDirection);
// find source cell
CCellMap::const_iterator index = m_map.find(getCanonicalName(srcName));
if (index == m_map.end()) {
return CString();
}
// find edge
const CCellEdge* srcEdge, *dstEdge;
if (!index->second.getLink(srcSide, position, srcEdge, dstEdge)) {
// no neighbor
return "";
}
else {
// compute position on neighbor
if (positionOut != NULL) {
*positionOut =
dstEdge->inverseTransform(srcEdge->transform(position));
}
// return neighbor's name
return getCanonicalName(dstEdge->getName());
}
}
bool
CConfig::hasNeighbor(const CString& srcName, EDirection srcSide) const
{
return hasNeighbor(srcName, srcSide, 0.0f, 1.0f);
}
bool
CConfig::hasNeighbor(const CString& srcName, EDirection srcSide,
float start, float end) const
{
assert(srcSide >= kFirstDirection && srcSide <= kLastDirection);
// find source cell
CCellMap::const_iterator index = m_map.find(getCanonicalName(srcName));
if (index == m_map.end()) {
return false;
}
return index->second.overlaps(CCellEdge(srcSide, CInterval(start, end)));
}
CConfig::link_const_iterator
CConfig::beginNeighbor(const CString& srcName) const
{
CCellMap::const_iterator index = m_map.find(getCanonicalName(srcName));
assert(index != m_map.end());
return index->second.begin();
}
CConfig::link_const_iterator
CConfig::endNeighbor(const CString& srcName) const
{
CCellMap::const_iterator index = m_map.find(getCanonicalName(srcName));
assert(index != m_map.end());
return index->second.end();
}
const CNetworkAddress&
CConfig::getSynergyAddress() const
{
return m_synergyAddress;
}
const CConfig::CScreenOptions*
CConfig::getOptions(const CString& name) const
{
// find options
const CScreenOptions* options = NULL;
if (name.empty()) {
options = &m_globalOptions;
}
else {
CCellMap::const_iterator index = m_map.find(name);
if (index != m_map.end()) {
options = &index->second.m_options;
}
}
// return options
return options;
}
bool
CConfig::hasLockToScreenAction() const
{
return m_hasLockToScreenAction;
}
bool
CConfig::operator==(const CConfig& x) const
{
if (m_synergyAddress != x.m_synergyAddress) {
return false;
}
if (m_map.size() != x.m_map.size()) {
return false;
}
if (m_nameToCanonicalName.size() != x.m_nameToCanonicalName.size()) {
return false;
}
// compare global options
if (m_globalOptions != x.m_globalOptions) {
return false;
}
for (CCellMap::const_iterator index1 = m_map.begin(),
index2 = x.m_map.begin();
index1 != m_map.end(); ++index1, ++index2) {
// compare names
if (!CStringUtil::CaselessCmp::equal(index1->first, index2->first)) {
return false;
}
// compare cells
if (index1->second != index2->second) {
return false;
}
}
for (CNameMap::const_iterator index1 = m_nameToCanonicalName.begin(),
index2 = x.m_nameToCanonicalName.begin();
index1 != m_nameToCanonicalName.end();
++index1, ++index2) {
if (!CStringUtil::CaselessCmp::equal(index1->first, index2->first) ||
!CStringUtil::CaselessCmp::equal(index1->second, index2->second)) {
return false;
}
}
// compare input filters
if (m_inputFilter != x.m_inputFilter) {
return false;
}
return true;
}
bool
CConfig::operator!=(const CConfig& x) const
{
return !operator==(x);
}
void
CConfig::read(CConfigReadContext& context)
{
CConfig tmp;
while (context) {
tmp.readSection(context);
}
*this = tmp;
}
const char*
CConfig::dirName(EDirection dir)
{
static const char* s_name[] = { "left", "right", "up", "down" };
assert(dir >= kFirstDirection && dir <= kLastDirection);
return s_name[dir - kFirstDirection];
}
CInputFilter*
CConfig::getInputFilter()
{
return &m_inputFilter;
}
CString
CConfig::formatInterval(const CInterval& x)
{
if (x.first == 0.0f && x.second == 1.0f) {
return "";
}
return CStringUtil::print("(%d,%d)", (int)(x.first * 100.0f + 0.5f),
(int)(x.second * 100.0f + 0.5f));
}
void
CConfig::readSection(CConfigReadContext& s)
{
static const char s_section[] = "section:";
static const char s_options[] = "options";
static const char s_screens[] = "screens";
static const char s_links[] = "links";
static const char s_aliases[] = "aliases";
CString line;
if (!s.readLine(line)) {
// no more sections
return;
}
// should be a section header
if (line.find(s_section) != 0) {
throw XConfigRead(s, "found data outside section");
}
// get section name
CString::size_type i = line.find_first_not_of(" \t", sizeof(s_section) - 1);
if (i == CString::npos) {
throw XConfigRead(s, "section name is missing");
}
CString name = line.substr(i);
i = name.find_first_of(" \t");
if (i != CString::npos) {
throw XConfigRead(s, "unexpected data after section name");
}
// read section
if (name == s_options) {
readSectionOptions(s);
}
else if (name == s_screens) {
readSectionScreens(s);
}
else if (name == s_links) {
readSectionLinks(s);
}
else if (name == s_aliases) {
readSectionAliases(s);
}
else {
throw XConfigRead(s, "unknown section name \"%{1}\"", name);
}
}
void
CConfig::readSectionOptions(CConfigReadContext& s)
{
CString line;
while (s.readLine(line)) {
// check for end of section
if (line == "end") {
return;
}
// parse argument: `nameAndArgs = [values][;[values]]'
// nameAndArgs := <name>[(arg[,...])]
// values := valueAndArgs[,valueAndArgs]...
// valueAndArgs := <value>[(arg[,...])]
CString::size_type i = 0;
CString name, value;
CConfigReadContext::ArgList nameArgs, valueArgs;
s.parseNameWithArgs("name", line, "=", i, name, nameArgs);
++i;
s.parseNameWithArgs("value", line, ",;\n", i, value, valueArgs);
bool handled = true;
if (name == "address") {
try {
m_synergyAddress = CNetworkAddress(value, kDefaultPort);
m_synergyAddress.resolve();
}
catch (XSocketAddress& e) {
throw XConfigRead(s,
CString("invalid address argument ") + e.what());
}
}
else if (name == "heartbeat") {
addOption("", kOptionHeartbeat, s.parseInt(value));
}
else if (name == "switchCorners") {
addOption("", kOptionScreenSwitchCorners, s.parseCorners(value));
}
else if (name == "switchCornerSize") {
addOption("", kOptionScreenSwitchCornerSize, s.parseInt(value));
}
else if (name == "switchDelay") {
addOption("", kOptionScreenSwitchDelay, s.parseInt(value));
}
else if (name == "switchDoubleTap") {
addOption("", kOptionScreenSwitchTwoTap, s.parseInt(value));
}
else if (name == "screenSaverSync") {
addOption("", kOptionScreenSaverSync, s.parseBoolean(value));
}
else if (name == "relativeMouseMoves") {
addOption("", kOptionRelativeMouseMoves, s.parseBoolean(value));
}
else if (name == "win32KeepForeground") {
addOption("", kOptionWin32KeepForeground, s.parseBoolean(value));
}
else {
handled = false;
}
if (handled) {
// make sure handled options aren't followed by more values
if (i < line.size() && (line[i] == ',' || line[i] == ';')) {
throw XConfigRead(s, "to many arguments to %s", name.c_str());
}
}
else {
// make filter rule
CInputFilter::CRule rule(parseCondition(s, name, nameArgs));
// save first action (if any)
if (!value.empty() || line[i] != ';') {
parseAction(s, value, valueArgs, rule, true);
}
// get remaining activate actions
while (i < line.length() && line[i] != ';') {
++i;
s.parseNameWithArgs("value", line, ",;\n", i, value, valueArgs);
parseAction(s, value, valueArgs, rule, true);
}
// get deactivate actions
if (i < line.length() && line[i] == ';') {
// allow trailing ';'
i = line.find_first_not_of(" \t", i + 1);
if (i == CString::npos) {
i = line.length();
}
else {
--i;
}
// get actions
while (i < line.length()) {
++i;
s.parseNameWithArgs("value", line, ",\n",
i, value, valueArgs);
parseAction(s, value, valueArgs, rule, false);
}
}
// add rule
m_inputFilter.addFilterRule(rule);
}
}
throw XConfigRead(s, "unexpected end of options section");
}
void
CConfig::readSectionScreens(CConfigReadContext& s)
{
CString line;
CString screen;
while (s.readLine(line)) {
// check for end of section
if (line == "end") {
return;
}
// see if it's the next screen
if (line[line.size() - 1] == ':') {
// strip :
screen = line.substr(0, line.size() - 1);
// verify validity of screen name
if (!isValidScreenName(screen)) {
throw XConfigRead(s, "invalid screen name \"%{1}\"", screen);
}
// add the screen to the configuration
if (!addScreen(screen)) {
throw XConfigRead(s, "duplicate screen name \"%{1}\"", screen);
}
}
else if (screen.empty()) {
throw XConfigRead(s, "argument before first screen");
}
else {
// parse argument: `<name>=<value>'
CString::size_type i = line.find_first_of(" \t=");
if (i == 0) {
throw XConfigRead(s, "missing argument name");
}
if (i == CString::npos) {
throw XConfigRead(s, "missing =");
}
CString name = line.substr(0, i);
i = line.find_first_not_of(" \t", i);
if (i == CString::npos || line[i] != '=') {
throw XConfigRead(s, "missing =");
}
i = line.find_first_not_of(" \t", i + 1);
CString value;
if (i != CString::npos) {
value = line.substr(i);
}
// handle argument
if (name == "halfDuplexCapsLock") {
addOption(screen, kOptionHalfDuplexCapsLock,
s.parseBoolean(value));
}
else if (name == "halfDuplexNumLock") {
addOption(screen, kOptionHalfDuplexNumLock,
s.parseBoolean(value));
}
else if (name == "halfDuplexScrollLock") {
addOption(screen, kOptionHalfDuplexScrollLock,
s.parseBoolean(value));
}
else if (name == "shift") {
addOption(screen, kOptionModifierMapForShift,
s.parseModifierKey(value));
}
else if (name == "ctrl") {
addOption(screen, kOptionModifierMapForControl,
s.parseModifierKey(value));
}
else if (name == "alt") {
addOption(screen, kOptionModifierMapForAlt,
s.parseModifierKey(value));
}
else if (name == "meta") {
addOption(screen, kOptionModifierMapForMeta,
s.parseModifierKey(value));
}
else if (name == "super") {
addOption(screen, kOptionModifierMapForSuper,
s.parseModifierKey(value));
}
else if (name == "xtestIsXineramaUnaware") {
addOption(screen, kOptionXTestXineramaUnaware,
s.parseBoolean(value));
}
else if (name == "switchCorners") {
addOption(screen, kOptionScreenSwitchCorners,
s.parseCorners(value));
}
else if (name == "switchCornerSize") {
addOption(screen, kOptionScreenSwitchCornerSize,
s.parseInt(value));
}
else if (name == "preserveFocus") {
addOption(screen, kOptionScreenPreserveFocus,
s.parseBoolean(value));
}
else {
// unknown argument
throw XConfigRead(s, "unknown argument \"%{1}\"", name);
}
}
}
throw XConfigRead(s, "unexpected end of screens section");
}
void
CConfig::readSectionLinks(CConfigReadContext& s)
{
CString line;
CString screen;
while (s.readLine(line)) {
// check for end of section
if (line == "end") {
return;
}
// see if it's the next screen
if (line[line.size() - 1] == ':') {
// strip :
screen = line.substr(0, line.size() - 1);
// verify we know about the screen
if (!isScreen(screen)) {
throw XConfigRead(s, "unknown screen name \"%{1}\"", screen);
}
if (!isCanonicalName(screen)) {
throw XConfigRead(s, "cannot use screen name alias here");
}
}
else if (screen.empty()) {
throw XConfigRead(s, "argument before first screen");
}
else {
// parse argument: `<name>[(<s0>,<e0>)]=<value>[(<s1>,<e1>)]'
// the stuff in brackets is optional. interval values must be
// in the range [0,100] and start < end. if not given the
// interval is taken to be (0,100).
CString::size_type i = 0;
CString side, dstScreen, srcArgString, dstArgString;
CConfigReadContext::ArgList srcArgs, dstArgs;
s.parseNameWithArgs("link", line, "=", i, side, srcArgs);
++i;
s.parseNameWithArgs("screen", line, "", i, dstScreen, dstArgs);
CInterval srcInterval(s.parseInterval(srcArgs));
CInterval dstInterval(s.parseInterval(dstArgs));
// handle argument
EDirection dir;
if (side == "left") {
dir = kLeft;
}
else if (side == "right") {
dir = kRight;
}
else if (side == "up") {
dir = kTop;
}
else if (side == "down") {
dir = kBottom;
}
else {
// unknown argument
throw XConfigRead(s, "unknown side \"%{1}\" in link", side);
}
if (!isScreen(dstScreen)) {
throw XConfigRead(s, "unknown screen name \"%{1}\"", dstScreen);
}
if (!connect(screen, dir,
srcInterval.first, srcInterval.second,
dstScreen,
dstInterval.first, dstInterval.second)) {
throw XConfigRead(s, "overlapping range");
}
}
}
throw XConfigRead(s, "unexpected end of links section");
}
void
CConfig::readSectionAliases(CConfigReadContext& s)
{
CString line;
CString screen;
while (s.readLine(line)) {
// check for end of section
if (line == "end") {
return;
}
// see if it's the next screen
if (line[line.size() - 1] == ':') {
// strip :
screen = line.substr(0, line.size() - 1);
// verify we know about the screen
if (!isScreen(screen)) {
throw XConfigRead(s, "unknown screen name \"%{1}\"", screen);
}
if (!isCanonicalName(screen)) {
throw XConfigRead(s, "cannot use screen name alias here");
}
}
else if (screen.empty()) {
throw XConfigRead(s, "argument before first screen");
}
else {
// verify validity of screen name
if (!isValidScreenName(line)) {
throw XConfigRead(s, "invalid screen alias \"%{1}\"", line);
}
// add alias
if (!addAlias(screen, line)) {
throw XConfigRead(s, "alias \"%{1}\" is already used", line);
}
}
}
throw XConfigRead(s, "unexpected end of aliases section");
}
CInputFilter::CCondition*
CConfig::parseCondition(CConfigReadContext& s,
const CString& name, const std::vector<CString>& args)
{
if (name == "keystroke") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for condition: keystroke(modifiers+key)");
}
IPlatformScreen::CKeyInfo* keyInfo = s.parseKeystroke(args[0]);
return new CInputFilter::CKeystrokeCondition(keyInfo);
}
if (name == "mousebutton") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for condition: mousebutton(modifiers+button)");
}
IPlatformScreen::CButtonInfo* mouseInfo = s.parseMouse(args[0]);
return new CInputFilter::CMouseButtonCondition(mouseInfo);
}
if (name == "connect") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for condition: connect([screen])");
}
CString screen = args[0];
if (isScreen(screen)) {
screen = getCanonicalName(screen);
}
else if (!screen.empty()) {
throw XConfigRead(s, "unknown screen name \"%{1}\" in connect", screen);
}
return new CInputFilter::CScreenConnectedCondition(screen);
}
throw XConfigRead(s, "unknown argument \"%{1}\"", name);
}
void
CConfig::parseAction(CConfigReadContext& s,
const CString& name, const std::vector<CString>& args,
CInputFilter::CRule& rule, bool activate)
{
CInputFilter::CAction* action;
if (name == "keystroke" || name == "keyDown" || name == "keyUp") {
if (args.size() < 1 || args.size() > 2) {
throw XConfigRead(s, "syntax for action: keystroke(modifiers+key[,screens])");
}
IPlatformScreen::CKeyInfo* keyInfo;
if (args.size() == 1) {
keyInfo = s.parseKeystroke(args[0]);
}
else {
std::set<CString> screens;
parseScreens(s, args[1], screens);
keyInfo = s.parseKeystroke(args[0], screens);
}
if (name == "keystroke") {
IPlatformScreen::CKeyInfo* keyInfo2 =
IKeyState::CKeyInfo::alloc(*keyInfo);
action = new CInputFilter::CKeystrokeAction(keyInfo2, true);
rule.adoptAction(action, true);
action = new CInputFilter::CKeystrokeAction(keyInfo, false);
activate = false;
}
else if (name == "keyDown") {
action = new CInputFilter::CKeystrokeAction(keyInfo, true);
}
else {
action = new CInputFilter::CKeystrokeAction(keyInfo, false);
}
}
else if (name == "mousebutton" ||
name == "mouseDown" || name == "mouseUp") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for action: mousebutton(modifiers+button)");
}
IPlatformScreen::CButtonInfo* mouseInfo = s.parseMouse(args[0]);
if (name == "mousebutton") {
IPlatformScreen::CButtonInfo* mouseInfo2 =
IPlatformScreen::CButtonInfo::alloc(*mouseInfo);
action = new CInputFilter::CMouseButtonAction(mouseInfo2, true);
rule.adoptAction(action, true);
action = new CInputFilter::CMouseButtonAction(mouseInfo, false);
activate = false;
}
else if (name == "mouseDown") {
action = new CInputFilter::CMouseButtonAction(mouseInfo, true);
}
else {
action = new CInputFilter::CMouseButtonAction(mouseInfo, false);
}
}
/* XXX -- not supported
else if (name == "modifier") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for action: modifier(modifiers)");
}
KeyModifierMask mask = s.parseModifier(args[0]);
action = new CInputFilter::CModifierAction(mask, ~mask);
}
*/
else if (name == "switchToScreen") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for action: switchToScreen(name)");
}
CString screen = args[0];
if (isScreen(screen)) {
screen = getCanonicalName(screen);
}
else if (!screen.empty()) {
throw XConfigRead(s, "unknown screen name in switchToScreen");
}
action = new CInputFilter::CSwitchToScreenAction(screen);
}
else if (name == "switchInDirection") {
if (args.size() != 1) {
throw XConfigRead(s, "syntax for action: switchInDirection(<left|right|up|down>)");
}
EDirection direction;
if (args[0] == "left") {
direction = kLeft;
}
else if (args[0] == "right") {
direction = kRight;
}
else if (args[0] == "up") {
direction = kTop;
}
else if (args[0] == "down") {
direction = kBottom;
}
else {
throw XConfigRead(s, "unknown direction \"%{1}\" in switchToScreen", args[0]);
}
action = new CInputFilter::CSwitchInDirectionAction(direction);
}
else if (name == "lockCursorToScreen") {
if (args.size() > 1) {
throw XConfigRead(s, "syntax for action: lockCursorToScreen([{off|on|toggle}])");
}
CInputFilter::CLockCursorToScreenAction::Mode mode =
CInputFilter::CLockCursorToScreenAction::kToggle;
if (args.size() == 1) {
if (args[0] == "off") {
mode = CInputFilter::CLockCursorToScreenAction::kOff;
}
else if (args[0] == "on") {
mode = CInputFilter::CLockCursorToScreenAction::kOn;
}
else if (args[0] == "toggle") {
mode = CInputFilter::CLockCursorToScreenAction::kToggle;
}
else {
throw XConfigRead(s, "syntax for action: lockCursorToScreen([{off|on|toggle}])");
}
}
if (mode != CInputFilter::CLockCursorToScreenAction::kOff) {
m_hasLockToScreenAction = true;
}
action = new CInputFilter::CLockCursorToScreenAction(mode);
}
else if (name == "keyboardBroadcast") {
if (args.size() > 2) {
throw XConfigRead(s, "syntax for action: keyboardBroadcast([{off|on|toggle}[,screens]])");
}
CInputFilter::CKeyboardBroadcastAction::Mode mode =
CInputFilter::CKeyboardBroadcastAction::kToggle;
if (args.size() >= 1) {
if (args[0] == "off") {
mode = CInputFilter::CKeyboardBroadcastAction::kOff;
}
else if (args[0] == "on") {
mode = CInputFilter::CKeyboardBroadcastAction::kOn;
}
else if (args[0] == "toggle") {
mode = CInputFilter::CKeyboardBroadcastAction::kToggle;
}
else {
throw XConfigRead(s, "syntax for action: keyboardBroadcast([{off|on|toggle}[,screens]])");
}
}
std::set<CString> screens;
if (args.size() >= 2) {
parseScreens(s, args[1], screens);
}
action = new CInputFilter::CKeyboardBroadcastAction(mode, screens);
}
else {
throw XConfigRead(s, "unknown action argument \"%{1}\"", name);
}
rule.adoptAction(action, activate);
}
void
CConfig::parseScreens(CConfigReadContext& c,
const CString& s, std::set<CString>& screens) const
{
screens.clear();
CString::size_type i = 0;
while (i < s.size()) {
// find end of next screen name
CString::size_type j = s.find(':', i);
if (j == CString::npos) {
j = s.size();
}
// extract name
CString rawName;
i = s.find_first_not_of(" \t", i);
if (i < j) {
rawName = s.substr(i, s.find_last_not_of(" \t", j - 1) - i + 1);
}
// add name
if (rawName == "*") {
screens.insert("*");
}
else if (!rawName.empty()) {
CString name = getCanonicalName(rawName);
if (name.empty()) {
throw XConfigRead(c, "unknown screen name \"%{1}\"", rawName);
}
screens.insert(name);
}
// next
i = j + 1;
}
}
const char*
CConfig::getOptionName(OptionID id)
{
if (id == kOptionHalfDuplexCapsLock) {
return "halfDuplexCapsLock";
}
if (id == kOptionHalfDuplexNumLock) {
return "halfDuplexNumLock";
}
if (id == kOptionHalfDuplexScrollLock) {
return "halfDuplexScrollLock";
}
if (id == kOptionModifierMapForShift) {
return "shift";
}
if (id == kOptionModifierMapForControl) {
return "ctrl";
}
if (id == kOptionModifierMapForAlt) {
return "alt";
}
if (id == kOptionModifierMapForMeta) {
return "meta";
}
if (id == kOptionModifierMapForSuper) {
return "super";
}
if (id == kOptionHeartbeat) {
return "heartbeat";
}
if (id == kOptionScreenSwitchCorners) {
return "switchCorners";
}
if (id == kOptionScreenSwitchCornerSize) {
return "switchCornerSize";
}
if (id == kOptionScreenSwitchDelay) {
return "switchDelay";
}
if (id == kOptionScreenSwitchTwoTap) {
return "switchDoubleTap";
}
if (id == kOptionScreenSaverSync) {
return "screenSaverSync";
}
if (id == kOptionXTestXineramaUnaware) {
return "xtestIsXineramaUnaware";
}
if (id == kOptionRelativeMouseMoves) {
return "relativeMouseMoves";
}
if (id == kOptionWin32KeepForeground) {
return "win32KeepForeground";
}
if (id == kOptionScreenPreserveFocus) {
return "preserveFocus";
}
return NULL;
}
CString
CConfig::getOptionValue(OptionID id, OptionValue value)
{
if (id == kOptionHalfDuplexCapsLock ||
id == kOptionHalfDuplexNumLock ||
id == kOptionHalfDuplexScrollLock ||
id == kOptionScreenSaverSync ||
id == kOptionXTestXineramaUnaware ||
id == kOptionRelativeMouseMoves ||
id == kOptionWin32KeepForeground ||
id == kOptionScreenPreserveFocus) {
return (value != 0) ? "true" : "false";
}
if (id == kOptionModifierMapForShift ||
id == kOptionModifierMapForControl ||
id == kOptionModifierMapForAlt ||
id == kOptionModifierMapForMeta ||
id == kOptionModifierMapForSuper) {
switch (value) {
case kKeyModifierIDShift:
return "shift";
case kKeyModifierIDControl:
return "ctrl";
case kKeyModifierIDAlt:
return "alt";
case kKeyModifierIDMeta:
return "meta";
case kKeyModifierIDSuper:
return "super";
default:
return "none";
}
}
if (id == kOptionHeartbeat ||
id == kOptionScreenSwitchCornerSize ||
id == kOptionScreenSwitchDelay ||
id == kOptionScreenSwitchTwoTap) {
return CStringUtil::print("%d", value);
}
if (id == kOptionScreenSwitchCorners) {
std::string result("none");
if ((value & kTopLeftMask) != 0) {
result += " +top-left";
}
if ((value & kTopRightMask) != 0) {
result += " +top-right";
}
if ((value & kBottomLeftMask) != 0) {
result += " +bottom-left";
}
if ((value & kBottomRightMask) != 0) {
result += " +bottom-right";
}
return result;
}
return "";
}
//
// CConfig::CName
//
CConfig::CName::CName(CConfig* config, const CString& name) :
m_config(config),
m_name(config->getCanonicalName(name))
{
// do nothing
}
bool
CConfig::CName::operator==(const CString& name) const
{
CString canonical = m_config->getCanonicalName(name);
return CStringUtil::CaselessCmp::equal(canonical, m_name);
}
//
// CConfig::CCellEdge
//
CConfig::CCellEdge::CCellEdge(EDirection side, float position)
{
init("", side, CInterval(position, position));
}
CConfig::CCellEdge::CCellEdge(EDirection side, const CInterval& interval)
{
assert(interval.first >= 0.0f);
assert(interval.second <= 1.0f);
assert(interval.first < interval.second);
init("", side, interval);
}
CConfig::CCellEdge::CCellEdge(const CString& name,
EDirection side, const CInterval& interval)
{
assert(interval.first >= 0.0f);
assert(interval.second <= 1.0f);
assert(interval.first < interval.second);
init(name, side, interval);
}
CConfig::CCellEdge::~CCellEdge()
{
// do nothing
}
void
CConfig::CCellEdge::init(const CString& name, EDirection side,
const CInterval& interval)
{
assert(side != kNoDirection);
m_name = name;
m_side = side;
m_interval = interval;
}
CConfig::CInterval
CConfig::CCellEdge::getInterval() const
{
return m_interval;
}
void
CConfig::CCellEdge::setName(const CString& newName)
{
m_name = newName;
}
CString
CConfig::CCellEdge::getName() const
{
return m_name;
}
EDirection
CConfig::CCellEdge::getSide() const
{
return m_side;
}
bool
CConfig::CCellEdge::overlaps(const CCellEdge& edge) const
{
const CInterval& x = m_interval;
const CInterval& y = edge.m_interval;
if (m_side != edge.m_side) {
return false;
}
return (x.first >= y.first && x.first < y.second) ||
(x.second > y.first && x.second <= y.second) ||
(y.first >= x.first && y.first < x.second) ||
(y.second > x.first && y.second <= x.second);
}
bool
CConfig::CCellEdge::isInside(float x) const
{
return (x >= m_interval.first && x < m_interval.second);
}
float
CConfig::CCellEdge::transform(float x) const
{
return (x - m_interval.first) / (m_interval.second - m_interval.first);
}
float
CConfig::CCellEdge::inverseTransform(float x) const
{
return x * (m_interval.second - m_interval.first) + m_interval.first;
}
bool
CConfig::CCellEdge::operator<(const CCellEdge& o) const
{
if (static_cast<int>(m_side) < static_cast<int>(o.m_side)) {
return true;
}
else if (static_cast<int>(m_side) > static_cast<int>(o.m_side)) {
return false;
}
return (m_interval.first < o.m_interval.first);
}
bool
CConfig::CCellEdge::operator==(const CCellEdge& x) const
{
return (m_side == x.m_side && m_interval == x.m_interval);
}
bool
CConfig::CCellEdge::operator!=(const CCellEdge& x) const
{
return !operator==(x);
}
//
// CConfig::CCell
//
bool
CConfig::CCell::add(const CCellEdge& src, const CCellEdge& dst)
{
// cannot add an edge that overlaps other existing edges but we
// can exactly replace an edge.
if (!hasEdge(src) && overlaps(src)) {
return false;
}
m_neighbors.erase(src);
m_neighbors.insert(std::make_pair(src, dst));
return true;
}
void
CConfig::CCell::remove(EDirection side)
{
for (CEdgeLinks::iterator j = m_neighbors.begin();
j != m_neighbors.end(); ) {
if (j->first.getSide() == side) {
m_neighbors.erase(j++);
}
else {
++j;
}
}
}
void
CConfig::CCell::remove(EDirection side, float position)
{
for (CEdgeLinks::iterator j = m_neighbors.begin();
j != m_neighbors.end(); ++j) {
if (j->first.getSide() == side && j->first.isInside(position)) {
m_neighbors.erase(j);
break;
}
}
}
void
CConfig::CCell::remove(const CName& name)
{
for (CEdgeLinks::iterator j = m_neighbors.begin();
j != m_neighbors.end(); ) {
if (name == j->second.getName()) {
m_neighbors.erase(j++);
}
else {
++j;
}
}
}
void
CConfig::CCell::rename(const CName& oldName, const CString& newName)
{
for (CEdgeLinks::iterator j = m_neighbors.begin();
j != m_neighbors.end(); ++j) {
if (oldName == j->second.getName()) {
j->second.setName(newName);
}
}
}
bool
CConfig::CCell::hasEdge(const CCellEdge& edge) const
{
CEdgeLinks::const_iterator i = m_neighbors.find(edge);
return (i != m_neighbors.end() && i->first == edge);
}
bool
CConfig::CCell::overlaps(const CCellEdge& edge) const
{
CEdgeLinks::const_iterator i = m_neighbors.upper_bound(edge);
if (i != m_neighbors.end() && i->first.overlaps(edge)) {
return true;
}
if (i != m_neighbors.begin() && (--i)->first.overlaps(edge)) {
return true;
}
return false;
}
bool
CConfig::CCell::getLink(EDirection side, float position,
const CCellEdge*& src, const CCellEdge*& dst) const
{
CCellEdge edge(side, position);
CEdgeLinks::const_iterator i = m_neighbors.upper_bound(edge);
if (i == m_neighbors.begin()) {
return false;
}
--i;
if (i->first.getSide() == side && i->first.isInside(position)) {
src = &i->first;
dst = &i->second;
return true;
}
return false;
}
bool
CConfig::CCell::operator==(const CCell& x) const
{
// compare options
if (m_options != x.m_options) {
return false;
}
// compare links
if (m_neighbors.size() != x.m_neighbors.size()) {
return false;
}
for (CEdgeLinks::const_iterator index1 = m_neighbors.begin(),
index2 = x.m_neighbors.begin();
index1 != m_neighbors.end();
++index1, ++index2) {
if (index1->first != index2->first) {
return false;
}
if (index1->second != index2->second) {
return false;
}
// operator== doesn't compare names. only compare destination
// names.
if (!CStringUtil::CaselessCmp::equal(index1->second.getName(),
index2->second.getName())) {
return false;
}
}
return true;
}
bool
CConfig::CCell::operator!=(const CCell& x) const
{
return !operator==(x);
}
CConfig::CCell::const_iterator
CConfig::CCell::begin() const
{
return m_neighbors.begin();
}
CConfig::CCell::const_iterator
CConfig::CCell::end() const
{
return m_neighbors.end();
}
//
// CConfig I/O
//
std::istream&
operator>>(std::istream& s, CConfig& config)
{
CConfigReadContext context(s);
config.read(context);
return s;
}
std::ostream&
operator<<(std::ostream& s, const CConfig& config)
{
// screens section
s << "section: screens" << std::endl;
for (CConfig::const_iterator screen = config.begin();
screen != config.end(); ++screen) {
s << "\t" << screen->c_str() << ":" << std::endl;
const CConfig::CScreenOptions* options = config.getOptions(*screen);
if (options != NULL && options->size() > 0) {
for (CConfig::CScreenOptions::const_iterator
option = options->begin();
option != options->end(); ++option) {
const char* name = CConfig::getOptionName(option->first);
CString value = CConfig::getOptionValue(option->first,
option->second);
if (name != NULL && !value.empty()) {
s << "\t\t" << name << " = " << value << std::endl;
}
}
}
}
s << "end" << std::endl;
// links section
CString neighbor;
s << "section: links" << std::endl;
for (CConfig::const_iterator screen = config.begin();
screen != config.end(); ++screen) {
s << "\t" << screen->c_str() << ":" << std::endl;
for (CConfig::link_const_iterator
link = config.beginNeighbor(*screen),
nend = config.endNeighbor(*screen); link != nend; ++link) {
s << "\t\t" << CConfig::dirName(link->first.getSide()) <<
CConfig::formatInterval(link->first.getInterval()) <<
" = " << link->second.getName().c_str() <<
CConfig::formatInterval(link->second.getInterval()) <<
std::endl;
}
}
s << "end" << std::endl;
// aliases section (if there are any)
if (config.m_map.size() != config.m_nameToCanonicalName.size()) {
// map canonical to alias
typedef std::multimap<CString, CString,
CStringUtil::CaselessCmp> CMNameMap;
CMNameMap aliases;
for (CConfig::CNameMap::const_iterator
index = config.m_nameToCanonicalName.begin();
index != config.m_nameToCanonicalName.end();
++index) {
if (index->first != index->second) {
aliases.insert(std::make_pair(index->second, index->first));
}
}
// dump it
CString screen;
s << "section: aliases" << std::endl;
for (CMNameMap::const_iterator index = aliases.begin();
index != aliases.end(); ++index) {
if (index->first != screen) {
screen = index->first;
s << "\t" << screen.c_str() << ":" << std::endl;
}
s << "\t\t" << index->second.c_str() << std::endl;
}
s << "end" << std::endl;
}
// options section
s << "section: options" << std::endl;
const CConfig::CScreenOptions* options = config.getOptions("");
if (options != NULL && options->size() > 0) {
for (CConfig::CScreenOptions::const_iterator
option = options->begin();
option != options->end(); ++option) {
const char* name = CConfig::getOptionName(option->first);
CString value = CConfig::getOptionValue(option->first,
option->second);
if (name != NULL && !value.empty()) {
s << "\t" << name << " = " << value << std::endl;
}
}
}
if (config.m_synergyAddress.isValid()) {
s << "\taddress = " <<
config.m_synergyAddress.getHostname().c_str() << std::endl;
}
s << config.m_inputFilter.format("\t");
s << "end" << std::endl;
return s;
}
//
// CConfigReadContext
//
CConfigReadContext::CConfigReadContext(std::istream& s, SInt32 firstLine) :
m_stream(s),
m_line(firstLine - 1)
{
// do nothing
}
CConfigReadContext::~CConfigReadContext()
{
// do nothing
}
bool
CConfigReadContext::readLine(CString& line)
{
++m_line;
while (std::getline(m_stream, line)) {
// strip leading whitespace
CString::size_type i = line.find_first_not_of(" \t");
if (i != CString::npos) {
line.erase(0, i);
}
// strip comments and then trailing whitespace
i = line.find('#');
if (i != CString::npos) {
line.erase(i);
}
i = line.find_last_not_of(" \r\t");
if (i != CString::npos) {
line.erase(i + 1);
}
// return non empty line
if (!line.empty()) {
// make sure there are no invalid characters
for (i = 0; i < line.length(); ++i) {
if (!isgraph(line[i]) && line[i] != ' ' && line[i] != '\t') {
throw XConfigRead(*this,
"invalid character %{1}",
CStringUtil::print("%#2x", line[i]));
}
}
return true;
}
// next line
++m_line;
}
return false;
}
UInt32
CConfigReadContext::getLineNumber() const
{
return m_line;
}
CConfigReadContext::operator void*() const
{
return m_stream;
}
bool
CConfigReadContext::operator!() const
{
return !m_stream;
}
OptionValue
CConfigReadContext::parseBoolean(const CString& arg) const
{
if (CStringUtil::CaselessCmp::equal(arg, "true")) {
return static_cast<OptionValue>(true);
}
if (CStringUtil::CaselessCmp::equal(arg, "false")) {
return static_cast<OptionValue>(false);
}
throw XConfigRead(*this, "invalid boolean argument \"%{1}\"", arg);
}
OptionValue
CConfigReadContext::parseInt(const CString& arg) const
{
const char* s = arg.c_str();
char* end;
long tmp = strtol(s, &end, 10);
if (*end != '\0') {
// invalid characters
throw XConfigRead(*this, "invalid integer argument \"%{1}\"", arg);
}
OptionValue value = static_cast<OptionValue>(tmp);
if (value != tmp) {
// out of range
throw XConfigRead(*this, "integer argument \"%{1}\" out of range", arg);
}
return value;
}
OptionValue
CConfigReadContext::parseModifierKey(const CString& arg) const
{
if (CStringUtil::CaselessCmp::equal(arg, "shift")) {
return static_cast<OptionValue>(kKeyModifierIDShift);
}
if (CStringUtil::CaselessCmp::equal(arg, "ctrl")) {
return static_cast<OptionValue>(kKeyModifierIDControl);
}
if (CStringUtil::CaselessCmp::equal(arg, "alt")) {
return static_cast<OptionValue>(kKeyModifierIDAlt);
}
if (CStringUtil::CaselessCmp::equal(arg, "meta")) {
return static_cast<OptionValue>(kKeyModifierIDMeta);
}
if (CStringUtil::CaselessCmp::equal(arg, "super")) {
return static_cast<OptionValue>(kKeyModifierIDSuper);
}
if (CStringUtil::CaselessCmp::equal(arg, "none")) {
return static_cast<OptionValue>(kKeyModifierIDNull);
}
throw XConfigRead(*this, "invalid argument \"%{1}\"", arg);
}
OptionValue
CConfigReadContext::parseCorner(const CString& arg) const
{
if (CStringUtil::CaselessCmp::equal(arg, "left")) {
return kTopLeftMask | kBottomLeftMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "right")) {
return kTopRightMask | kBottomRightMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "top")) {
return kTopLeftMask | kTopRightMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "bottom")) {
return kBottomLeftMask | kBottomRightMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "top-left")) {
return kTopLeftMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "top-right")) {
return kTopRightMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "bottom-left")) {
return kBottomLeftMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "bottom-right")) {
return kBottomRightMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "none")) {
return kNoCornerMask;
}
else if (CStringUtil::CaselessCmp::equal(arg, "all")) {
return kAllCornersMask;
}
throw XConfigRead(*this, "invalid argument \"%{1}\"", arg);
}
OptionValue
CConfigReadContext::parseCorners(const CString& args) const
{
// find first token
CString::size_type i = args.find_first_not_of(" \t", 0);
if (i == CString::npos) {
throw XConfigRead(*this, "missing corner argument");
}
CString::size_type j = args.find_first_of(" \t", i);
// parse first corner token
OptionValue corners = parseCorner(args.substr(i, j - i));
// get +/-
i = args.find_first_not_of(" \t", j);
while (i != CString::npos) {
// parse +/-
bool add;
if (args[i] == '-') {
add = false;
}
else if (args[i] == '+') {
add = true;
}
else {
throw XConfigRead(*this,
"invalid corner operator \"%{1}\"",
CString(args.c_str() + i, 1));
}
// get next corner token
i = args.find_first_not_of(" \t", i + 1);
j = args.find_first_of(" \t", i);
if (i == CString::npos) {
throw XConfigRead(*this, "missing corner argument");
}
// parse next corner token
if (add) {
corners |= parseCorner(args.substr(i, j - i));
}
else {
corners &= ~parseCorner(args.substr(i, j - i));
}
i = args.find_first_not_of(" \t", j);
}
return corners;
}
CConfig::CInterval
CConfigReadContext::parseInterval(const ArgList& args) const
{
if (args.size() == 0) {
return CConfig::CInterval(0.0f, 1.0f);
}
if (args.size() != 2 || args[0].empty() || args[1].empty()) {
throw XConfigRead(*this, "invalid interval \"%{1}\"", concatArgs(args));
}
char* end;
long startValue = strtol(args[0].c_str(), &end, 10);
if (end[0] != '\0') {
throw XConfigRead(*this, "invalid interval \"%{1}\"", concatArgs(args));
}
long endValue = strtol(args[1].c_str(), &end, 10);
if (end[0] != '\0') {
throw XConfigRead(*this, "invalid interval \"%{1}\"", concatArgs(args));
}
if (startValue < 0 || startValue > 100 ||
endValue < 0 || endValue > 100 ||
startValue >= endValue) {
throw XConfigRead(*this, "invalid interval \"%{1}\"", concatArgs(args));
}
return CConfig::CInterval(startValue / 100.0f, endValue / 100.0f);
}
void
CConfigReadContext::parseNameWithArgs(
const CString& type, const CString& line,
const CString& delim, CString::size_type& index,
CString& name, ArgList& args) const
{
// skip leading whitespace
CString::size_type i = line.find_first_not_of(" \t", index);
if (i == CString::npos) {
throw XConfigRead(*this, CString("missing ") + type);
}
// find end of name
CString::size_type j = line.find_first_of(" \t(" + delim, i);
if (j == CString::npos) {
j = line.length();
}
// save name
name = line.substr(i, j - i);
args.clear();
// is it okay to not find a delimiter?
bool needDelim = (!delim.empty() && delim.find('\n') == CString::npos);
// skip whitespace
i = line.find_first_not_of(" \t", j);
if (i == CString::npos && needDelim) {
// expected delimiter but didn't find it
throw XConfigRead(*this, CString("missing ") + delim[0]);
}
if (i == CString::npos) {
// no arguments
index = line.length();
return;
}
if (line[i] != '(') {
// no arguments
index = i;
return;
}
// eat '('
++i;
// parse arguments
j = line.find_first_of(",)", i);
while (j != CString::npos) {
// extract arg
CString arg(line.substr(i, j - i));
i = j;
// trim whitespace
j = arg.find_first_not_of(" \t");
if (j != CString::npos) {
arg.erase(0, j);
}
j = arg.find_last_not_of(" \t");
if (j != CString::npos) {
arg.erase(j + 1);
}
// save arg
args.push_back(arg);
// exit loop at end of arguments
if (line[i] == ')') {
break;
}
// eat ','
++i;
// next
j = line.find_first_of(",)", i);
}
// verify ')'
if (j == CString::npos) {
// expected )
throw XConfigRead(*this, "missing )");
}
// eat ')'
++i;
// skip whitespace
j = line.find_first_not_of(" \t", i);
if (j == CString::npos && needDelim) {
// expected delimiter but didn't find it
throw XConfigRead(*this, CString("missing ") + delim[0]);
}
// verify delimiter
if (needDelim && delim.find(line[j]) == CString::npos) {
throw XConfigRead(*this, CString("expected ") + delim[0]);
}
if (j == CString::npos) {
j = line.length();
}
index = j;
return;
}
IPlatformScreen::CKeyInfo*
CConfigReadContext::parseKeystroke(const CString& keystroke) const
{
return parseKeystroke(keystroke, std::set<CString>());
}
IPlatformScreen::CKeyInfo*
CConfigReadContext::parseKeystroke(const CString& keystroke,
const std::set<CString>& screens) const
{
CString s = keystroke;
KeyModifierMask mask;
if (!CKeyMap::parseModifiers(s, mask)) {
throw XConfigRead(*this, "unable to parse key modifiers");
}
KeyID key;
if (!CKeyMap::parseKey(s, key)) {
throw XConfigRead(*this, "unable to parse key");
}
if (key == kKeyNone && mask == 0) {
throw XConfigRead(*this, "missing key and/or modifiers in keystroke");
}
return IPlatformScreen::CKeyInfo::alloc(key, mask, 0, 0, screens);
}
IPlatformScreen::CButtonInfo*
CConfigReadContext::parseMouse(const CString& mouse) const
{
CString s = mouse;
KeyModifierMask mask;
if (!CKeyMap::parseModifiers(s, mask)) {
throw XConfigRead(*this, "unable to parse button modifiers");
}
char* end;
ButtonID button = (ButtonID)strtol(s.c_str(), &end, 10);
if (*end != '\0') {
throw XConfigRead(*this, "unable to parse button");
}
if (s.empty() || button <= 0) {
throw XConfigRead(*this, "invalid button");
}
return IPlatformScreen::CButtonInfo::alloc(button, mask);
}
KeyModifierMask
CConfigReadContext::parseModifier(const CString& modifiers) const
{
CString s = modifiers;
KeyModifierMask mask;
if (!CKeyMap::parseModifiers(s, mask)) {
throw XConfigRead(*this, "unable to parse modifiers");
}
if (mask == 0) {
throw XConfigRead(*this, "no modifiers specified");
}
return mask;
}
CString
CConfigReadContext::concatArgs(const ArgList& args)
{
CString s("(");
for (size_t i = 0; i < args.size(); ++i) {
if (i != 0) {
s += ",";
}
s += args[i];
}
s += ")";
return s;
}
//
// CConfig I/O exceptions
//
XConfigRead::XConfigRead(const CConfigReadContext& context,
const CString& error) :
m_error(CStringUtil::print("line %d: %s",
context.getLineNumber(), error.c_str()))
{
// do nothing
}
XConfigRead::XConfigRead(const CConfigReadContext& context,
const char* errorFmt, const CString& arg) :
m_error(CStringUtil::print("line %d: ", context.getLineNumber()) +
CStringUtil::format(errorFmt, arg.c_str()))
{
// do nothing
}
XConfigRead::~XConfigRead()
{
// do nothing
}
CString
XConfigRead::getWhat() const throw()
{
return format("XConfigRead", "read error: %{1}", m_error.c_str());
}