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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [tools/] [src/] [libcdl/] [interp.cxx] - Rev 637
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//{{{ Banner //============================================================================ // // interp.cxx // // Provide access to Tcl interpreters // //============================================================================ //####COPYRIGHTBEGIN#### // // ---------------------------------------------------------------------------- // Copyright (C) 2002 Bart Veer // Copyright (C) 1999, 2000, 2001 Red Hat, Inc. // // This file is part of the eCos host tools. // // This program is free software; you can redistribute it and/or modify it // under the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 of the License, or (at your option) // any later version. // // This program 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, write to the Free Software Foundation, Inc., // 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. // // ---------------------------------------------------------------------------- // //####COPYRIGHTEND#### //============================================================================ //#####DESCRIPTIONBEGIN#### // // Author(s): bartv // Contact(s): bartv // Date: 1999/01/20 // Version: 0.02 // //####DESCRIPTIONEND#### //============================================================================ //}}} //{{{ #include's // ---------------------------------------------------------------------------- #include "cdlconfig.h" // Get the infrastructure types, assertions, tracing and similar // facilities. #include <cyg/infra/cyg_ass.h> #include <cyg/infra/cyg_trac.h> // <cdl.hxx> defines everything implemented in this module. // It implicitly supplies <string>, <vector> and <map> because // the class definitions rely on these headers. It also brings // in <tcl.h> #include <cdlcore.hxx> //}}} //{{{ Statics // ---------------------------------------------------------------------------- // This key is used for accessing AssocData in the Tcl interpreters, // specifically the CdlInterpreter object. char* CdlInterpreterBody::cdlinterpreter_assoc_data_key = "__cdlinterpreter"; CYGDBG_DEFINE_MEMLEAK_COUNTER(CdlInterpreterBody); //}}} //{{{ CdlInterpreter:: creation // ---------------------------------------------------------------------------- // Default constructor. This will only get invoked via the make() static // member. CdlInterpreterBody::CdlInterpreterBody(Tcl_Interp* tcl_interp_arg) { CYG_REPORT_FUNCNAME("CdlInterpreter:: default constructor"); CYG_REPORT_FUNCARG2XV(this, tcl_interp_arg); CYG_PRECONDITIONC(0 != tcl_interp_arg); tcl_interp = tcl_interp_arg; owns_interp = false; parent = 0; toplevel = 0; transaction = 0; loadable = 0; container = 0; node = 0; context = ""; error_fn_ptr = 0; warning_fn_ptr = 0; current_commands = 0; cdl_result = false; CYGDBG_MEMLEAK_CONSTRUCTOR(); cdlinterpreterbody_cookie = CdlInterpreterBody_Magic; Tcl_SetAssocData(tcl_interp, cdlinterpreter_assoc_data_key, 0, static_cast<ClientData>(this)); CYG_POSTCONDITION_THISC(); CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // Create a new CDL interpreter. The underlying Tcl interpreter can be // supplied by the caller, or else a suitable interpreter will be created // with default settings. This default interpreter will only support Tcl, // not Tk. There is no call to any AppInit() function, no support for // autoloading packages, the "unknown" command is not implemented, and // no command files will be read in. // // It is convenient to provide immediate access to two Tcl variables, // cdl_version and cdl_interactive. CdlInterpreter CdlInterpreterBody::make(Tcl_Interp* tcl_interp_arg) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::make", "interpreter %p"); CYG_REPORT_FUNCARG1XV(tcl_interp_arg); Tcl_Interp* tcl_interp = tcl_interp_arg; if (0 == tcl_interp) { tcl_interp = Tcl_CreateInterp(); if (0 == tcl_interp) { throw std::bad_alloc(); } } else { // Make sure that this Tcl interpreter is not already used // for another CdlInterpreter object. ClientData tmp = Tcl_GetAssocData(tcl_interp, cdlinterpreter_assoc_data_key, 0); if (0 != tmp) { CYG_FAIL("Attempt to use a Tcl interpreter for multiple CDL interpreters"); throw std::bad_alloc(); } } CdlInterpreter result = 0; try { result = new CdlInterpreterBody(tcl_interp); std::string version = Cdl::get_library_version(); if (0 == Tcl_SetVar(tcl_interp, "cdl_version", CDL_TCL_CONST_CAST(char*,version.c_str()), TCL_GLOBAL_ONLY)) { throw std::bad_alloc(); } if (0 == Tcl_SetVar(tcl_interp, "cdl_interactive", CDL_TCL_CONST_CAST(char*, (Cdl::is_interactive() ? "1" : "0")), TCL_GLOBAL_ONLY)) { throw std::bad_alloc(); } } catch(std::bad_alloc) { if (0 == tcl_interp_arg) { Tcl_DeleteInterp(tcl_interp); } throw; } if (0 == tcl_interp_arg) { result->owns_interp = true; } CYG_POSTCONDITION_CLASSC(result); CYG_REPORT_RETVAL(result); return result; } // ---------------------------------------------------------------------------- // Given a toplevel and a loadable, create a new slave interpreter // for that loadable. There should be master interpreter associated // with the toplevel already. // // FIXME: do slave interpreters automatically see cdl_version and // cdl_interactive? CdlInterpreter CdlInterpreterBody::create_slave(CdlLoadable loadable_arg, bool safe) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::create_slave", "slave %p"); CYG_REPORT_FUNCARG3XV(this, loadable_arg, safe); CYG_PRECONDITION_THISC(); CYG_PRECONDITION(0 == parent, "slave interpreters cannot be created inside slaves"); CYG_PRECONDITION(0 != toplevel, "CDL's slave interpreters need an associated toplevel"); CYG_PRECONDITION_CLASSC(loadable_arg); // Slave interpreters need a name. Use a counter to create them uniquely. static cdl_int next_slave = 1; std::string slave_name; Cdl::integer_to_string(next_slave++, slave_name); slave_name = "slave" + slave_name; // FIXME: creating a slave that is not safe appears to fail. #if 0 Tcl_Interp* slave = Tcl_CreateSlave(interp, CDL_TCL_CONST_CAST(char*, slave_name.c_str()), safe); #else Tcl_Interp* slave = Tcl_CreateInterp(); #endif if (0 == slave) { throw std::bad_alloc(); } CdlInterpreter result = 0; try { result = new CdlInterpreterBody(slave); } catch(std::bad_alloc) { Tcl_DeleteInterp(slave); throw; } result->owns_interp = true; #if 0 try { slaves.push_back(result); } catch(std::bad_alloc) { delete result; throw; } #endif result->parent = this; result->set_toplevel(toplevel); result->loadable = loadable_arg; result->set_variable("cdl_version", get_variable("cdl_version")); result->set_variable("cdl_interactive", get_variable("cdl_interactive")); CYG_POSTCONDITION_CLASSC(result); CYG_REPORT_RETVAL(result); return result; } // ---------------------------------------------------------------------------- // Given an existing interpreter, turn it into a safe one. This is a one-way // transformation. void CdlInterpreterBody::make_safe(void) { CYG_REPORT_FUNCNAME("CdlInterpreter::make_safe"); CYG_PRECONDITION_THISC(); if (0 != Tcl_MakeSafe(tcl_interp)) { throw std::bad_alloc(); } CYG_REPORT_RETURN(); } //}}} //{{{ CdlInterpreter:: destructor // ---------------------------------------------------------------------------- // Default destructor. It is necessary to worry about any slave // interpreters, but otherwise there are no complications. CdlInterpreterBody::~CdlInterpreterBody() { CYG_REPORT_FUNCNAME("CdlInterpreter:: destructor"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); cdlinterpreterbody_cookie = CdlInterpreterBody_Invalid; parent = 0; toplevel = 0; transaction = 0; loadable = 0; container = 0; node = 0; context = ""; error_fn_ptr = 0; warning_fn_ptr = 0; current_commands = 0; cdl_result = false; // Make sure slave interpreters get deleted before the current one for (std::vector<CdlInterpreter>::iterator i = slaves.begin(); i != slaves.end(); i++) { delete *i; *i = 0; } Tcl_DeleteAssocData(tcl_interp, cdlinterpreter_assoc_data_key); if (owns_interp) { Tcl_DeleteInterp(tcl_interp); } owns_interp = false; tcl_interp = 0; CYGDBG_MEMLEAK_DESTRUCTOR(); CYG_REPORT_RETURN(); } //}}} //{{{ CdlInterpreter:: check_this() // ---------------------------------------------------------------------------- // check_this(). bool CdlInterpreterBody::check_this(cyg_assert_class_zeal zeal) const { if (CdlInterpreterBody_Magic != cdlinterpreterbody_cookie) return false; CYGDBG_MEMLEAK_CHECKTHIS(); switch(zeal) { case cyg_system_test : case cyg_extreme : if (slaves.size() > 0) { for (std::vector<CdlInterpreter>::const_iterator i = slaves.begin(); i != slaves.end(); i++) { if (!(*i)->check_this(cyg_quick)) { return false; } } } case cyg_thorough : if ((0 != toplevel) && !toplevel->check_this(cyg_quick)) { return false; } if ((0 != transaction) && !transaction->check_this(cyg_quick)) { return false; } if ((0 != loadable) && !loadable->check_this(cyg_quick)) { return false; } if ((0 != container) && !container->check_this(cyg_quick)) { return false; } if ((0 != node) && !node->check_this(cyg_quick)) { return false; } case cyg_quick : // For now only the toplevel interpreter should have slaves. if ((0 != parent) && (slaves.size() > 0)) { return false; } if( 0 == tcl_interp) { return false; } case cyg_trivial : case cyg_none : break; } return true; } //}}} //{{{ CdlInterpreter:: set_toplevel() etc. // ---------------------------------------------------------------------------- // Keep track of the current toplevel, container, etc. This gives commands // added to the Tcl interpreter a simple way of figuring out the current // state of the world so that properties get added to the right node, etc. // // set_toplevel() should only be called once, for the master interpreter // associated with a toplevel. All slave interpreters inherit this value. // // There is no set_loadable(), instead the loadable field is filled in // by create_slave() and cannot be changed. CdlToplevel CdlInterpreterBody::get_toplevel() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_toplevel", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlToplevel result = toplevel; CYG_REPORT_RETVAL(result); return result; } CdlTransaction CdlInterpreterBody::get_transaction() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_transaction", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlTransaction result = transaction; CYG_REPORT_RETVAL(result); return result; } CdlLoadable CdlInterpreterBody::get_loadable() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter:get_loadable", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlLoadable result = loadable; CYG_REPORT_RETVAL(result); return result; } CdlContainer CdlInterpreterBody::get_container() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_container", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlContainer result = container; CYG_REPORT_RETVAL(result); return result; } CdlNode CdlInterpreterBody::get_node() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_node", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlNode result = node; CYG_REPORT_RETVAL(result); return result; } std::string CdlInterpreterBody::get_context() const { CYG_REPORT_FUNCNAME("CdlInterpreter::get_context"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_REPORT_RETURN(); return context; } CdlDiagnosticFnPtr CdlInterpreterBody::get_error_fn_ptr() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_error_fn_ptr", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlDiagnosticFnPtr result = error_fn_ptr; CYG_REPORT_RETVAL(result); return result; } CdlDiagnosticFnPtr CdlInterpreterBody::get_warning_fn_ptr() const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_warning_fn_ptr", "result %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CdlDiagnosticFnPtr result = warning_fn_ptr; CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::set_toplevel(CdlToplevel new_toplevel) { CYG_REPORT_FUNCNAME("CdlInterpreter::set_toplevel"); CYG_REPORT_FUNCARG2XV(this, new_toplevel); CYG_PRECONDITION_THISC(); CYG_PRECONDITION(0 == toplevel, "changing toplevels is not allowed"); CYG_PRECONDITION_CLASSC(new_toplevel); toplevel = new_toplevel; CYG_REPORT_RETURN(); } void CdlInterpreterBody::set_transaction(CdlTransaction new_transaction) { CYG_REPORT_FUNCNAME("CdlInterpreter::set_transaction"); CYG_REPORT_FUNCARG2XV(this, new_transaction); CYG_PRECONDITION_THISC(); CYG_PRECONDITION_ZERO_OR_CLASSC(new_transaction); transaction = new_transaction; CYG_REPORT_RETURN(); } CdlContainer CdlInterpreterBody::push_container(CdlContainer new_container) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::push_container", "result %p"); CYG_REPORT_FUNCARG2XV(this, new_container); CYG_PRECONDITION_THISC(); CYG_PRECONDITION_CLASSC(new_container); CdlContainer result = container; container = new_container; CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::pop_container(CdlContainer old_container) { CYG_REPORT_FUNCNAME("CdlInterpreter::pop_container"); CYG_REPORT_FUNCARG2XV(this, old_container); CYG_PRECONDITION_THISC(); CYG_PRECONDITION_ZERO_OR_CLASSC(old_container); CYG_PRECONDITIONC(0 != container); container = old_container; CYG_REPORT_RETURN(); } CdlNode CdlInterpreterBody::push_node(CdlNode new_node) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::push_node", "result %p"); CYG_REPORT_FUNCARG2XV(this, new_node); CYG_PRECONDITION_THISC(); CYG_PRECONDITION_CLASSC(new_node); CdlNode result = node; node = new_node; CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::pop_node(CdlNode old_node) { CYG_REPORT_FUNCNAME("CdlInterpreter::pop_node"); CYG_REPORT_FUNCARG2XV(this, old_node); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC(0 != node); CYG_PRECONDITION_ZERO_OR_CLASSC(old_node); node = old_node; CYG_REPORT_RETURN(); } std::string CdlInterpreterBody::push_context(std::string new_context) { CYG_REPORT_FUNCNAME("CdlInterpreter::push_context"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != new_context); std::string result = context; context = new_context; return result; } void CdlInterpreterBody::pop_context(std::string old_context) { CYG_REPORT_FUNCNAME("CdlInterpreter::pop_context"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != context); context = old_context; CYG_REPORT_RETURN(); } CdlDiagnosticFnPtr CdlInterpreterBody::push_error_fn_ptr(CdlDiagnosticFnPtr new_fn_ptr) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::push_error_fn_ptr", "result %p"); CYG_REPORT_FUNCARG2XV(this, new_fn_ptr); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC(0 != new_fn_ptr); CdlDiagnosticFnPtr result = error_fn_ptr; error_fn_ptr = new_fn_ptr; CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::pop_error_fn_ptr(CdlDiagnosticFnPtr old_fn_ptr) { CYG_REPORT_FUNCNAME("CdlInterpreter::pop_error_fn_ptr"); CYG_REPORT_FUNCARG2XV(this, old_fn_ptr); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC(0 != error_fn_ptr); error_fn_ptr = old_fn_ptr; CYG_REPORT_RETURN(); } CdlDiagnosticFnPtr CdlInterpreterBody::push_warning_fn_ptr(CdlDiagnosticFnPtr new_fn_ptr) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::push_warning_fn_ptr", "result %p"); CYG_REPORT_FUNCARG2XV(this, new_fn_ptr); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC(0 != new_fn_ptr); CdlDiagnosticFnPtr result = warning_fn_ptr; warning_fn_ptr = new_fn_ptr; CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::pop_warning_fn_ptr(CdlDiagnosticFnPtr old_fn_ptr) { CYG_REPORT_FUNCNAME("CdlInterpreter::pop_warning_fn_ptr"); CYG_REPORT_FUNCARG2XV(this, old_fn_ptr); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC(0 != warning_fn_ptr); warning_fn_ptr = old_fn_ptr; CYG_REPORT_RETURN(); } //}}} //{{{ CdlInterpreter:: get information // ---------------------------------------------------------------------------- // Get hold of the underlying Tcl interpreter. This makes it easier to // use miscellaneous Tcl library facilities such as Tcl_SplitList() Tcl_Interp* CdlInterpreterBody::get_tcl_interpreter(void) const { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_tcl_interpreter", "interpreter %p"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); Tcl_Interp* result = tcl_interp; CYG_REPORT_RETVAL(result); return result; } //}}} //{{{ CdlInterpreter:: eval() // ---------------------------------------------------------------------------- // Evaluate a Cdl script held in a string. The result of this evaluation, // e.g. TCL_OK, is returned directly. The string result is made available // in an in-out parameter. // // According to the spec the underlying Tcl_Eval() routine needs to be able // to make temporary changes to the script, so the latter must be held in // writable memory. This requires a copy operation. int CdlInterpreterBody::eval(std::string script, std::string& str_result) { CYG_REPORT_FUNCNAMETYPE("CdInterpreter::eval", "result %d"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); int result = TCL_OK; int size = script.size(); // Distinguish between results set by the Tcl interpreter and results // set by CDL-related commands running in that interpreter. cdl_result = false; if (size < 2048) { char buf[2048]; script.copy(buf, size, 0); buf[size] = '\0'; result = Tcl_Eval(tcl_interp, buf); } else { char* buf = static_cast<char*>(malloc(script.size() + 1)); if (0 == buf) { this->set_result(CdlParse::construct_diagnostic(this, "internal error", "", "Out of memory")); result = TCL_ERROR; } else { script.copy(buf, size, 0); buf[size] = '\0'; result = Tcl_Eval(tcl_interp, buf); free(buf); } } // The distinction between TCL_OK and TCL_RETURN is probably not worth // worrying about. if (TCL_RETURN == result) { result = TCL_OK; } // If we have an error condition that was raised by the Tcl // interpreter rather than by the library, it needs to be // raised up to the library level. That way the error count // etc. are kept accurate. if ((TCL_OK != result) && !cdl_result) { const char* tcl_result = Tcl_GetStringResult(tcl_interp); if ((0 == tcl_result) || ('\0' == tcl_result[0])) { tcl_result = "Internal error, no additional information available."; } CdlParse::report_error(this, "", tcl_result); } str_result = Tcl_GetStringResult(tcl_interp); CYG_REPORT_RETVAL(result); return result; } // Ditto for Tcl Code that comes from a CDL file. Currently this is held // as a string. In future it may be appropriate to store a byte-compiled // version as well. int CdlInterpreterBody::eval_cdl_code(const cdl_tcl_code script, std::string& str_result) { CYG_REPORT_FUNCNAMETYPE("CdInterpreter::eval_cdl_code", "result %d"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); int result = TCL_OK; int size = script.size(); // Distinguish between results set by the Tcl interpreter and results // set by CDL-related commands running in that interpreter. cdl_result = false; if (size < 2048) { char buf[2048]; script.copy(buf, size, 0); buf[size] = '\0'; result = Tcl_Eval(tcl_interp, buf); } else { char* buf = static_cast<char*>(malloc(script.size() + 1)); if (0 == buf) { this->set_result(CdlParse::construct_diagnostic(this, "internal error", "", "Out of memory")); result = TCL_ERROR; } else { script.copy(buf, size, 0); buf[size] = '\0'; result = Tcl_Eval(tcl_interp, buf); free(buf); } } // The distinction between TCL_OK and TCL_RETURN is probably not worth // worrying about. if (TCL_RETURN == result) { result = TCL_OK; } // If we have an error condition that was raised by the Tcl // interpreter rather than by the library, it needs to be // raised up to the library level. That way the error count // etc. are kept accurate. if ((TCL_OK != result) && !cdl_result) { const char* tcl_result = Tcl_GetStringResult(tcl_interp); if ((0 == tcl_result) || ('\0' == tcl_result[0])) { tcl_result = "Internal error, no additional information available."; } CdlParse::report_error(this, "", tcl_result); } str_result = Tcl_GetStringResult(tcl_interp); CYG_REPORT_RETVAL(result); return result; } // Ditto for evaluating an entire file. int CdlInterpreterBody::eval_file(std::string script, std::string& str_result) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::eval_file", "result %d"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != script); // Distinguish between results set by the Tcl interpreter and results // set by CDL-related commands running in that interpreter. cdl_result = false; int result = Tcl_EvalFile(tcl_interp, CDL_TCL_CONST_CAST(char*, script.c_str())); // The distinction between TCL_OK and TCL_RETURN is probably not worth // worrying about. if (TCL_RETURN == result) { result = TCL_OK; } // If we have an error condition that was raised by the Tcl // interpreter rather than by the library, it needs to be // raised up to the library level. That way the error count // etc. are kept accurate. if ((TCL_OK != result) && !cdl_result) { const char* tcl_result = Tcl_GetStringResult(tcl_interp); if ((0 == tcl_result) || ('\0' == tcl_result[0])) { tcl_result = "Internal error, no additional information available."; } CdlParse::report_error(this, "", tcl_result); } str_result = Tcl_GetStringResult(tcl_interp); CYG_REPORT_RETVAL(result); return result; } // Variants for when the result string is of no interest int CdlInterpreterBody::eval(std::string script) { std::string result_string; return this->eval(script, result_string); } int CdlInterpreterBody::eval_cdl_code(const cdl_tcl_code script) { std::string result_string; return this->eval_cdl_code(script, result_string); } int CdlInterpreterBody::eval_file(std::string filename) { std::string result_string; return this->eval_file(filename, result_string); } //}}} //{{{ CdlInterpreter:: set_result() // ---------------------------------------------------------------------------- // Provide a way of setting an interpreter's result from a command implemented // in C++. void CdlInterpreterBody::set_result(std::string result) { CYG_REPORT_FUNCNAME("CdlInterpreter::set_result"); CYG_PRECONDITION_THISC(); Tcl_SetResult(tcl_interp, const_cast<char*>(result.c_str()), TCL_VOLATILE); this->cdl_result = true; CYG_REPORT_RETURN(); } bool CdlInterpreterBody::result_set_by_cdl() { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::result_set_by_cdl", "result %d"); CYG_PRECONDITION_THISC(); bool result = this->cdl_result; CYG_REPORT_RETVAL(result); return result; } // ---------------------------------------------------------------------------- // Also allow the result to be extracted again. std::string CdlInterpreterBody::get_result() { CYG_REPORT_FUNCNAME("CdlInterpreter::get_result"); CYG_PRECONDITION_THISC(); std::string result = Tcl_GetStringResult(tcl_interp); CYG_REPORT_RETURN(); return result; } //}}} //{{{ CdlInterpreter:: add and remove commands // ---------------------------------------------------------------------------- // This is the Tcl command proc that gets used for all CdlInterpreter // commands. The ClientData field will be a CdlInterpreterCommand, // i.e. a function pointer. That function needs a pointer to the // CdlInterpreter object, which can be accessed via AssocData. int CdlInterpreterBody::tcl_command_proc(ClientData data, Tcl_Interp* tcl_interp, int argc, const char* argv[]) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::tcl_command_proc", "result %d"); CYG_REPORT_FUNCARG3XV(data, tcl_interp, argc); CYG_PRECONDITIONC(0 != data); int result = TCL_OK; union { ClientData data; CdlInterpreterCommand command; } x; x.data = data; CdlInterpreterCommand command = x.command; data = Tcl_GetAssocData(tcl_interp, cdlinterpreter_assoc_data_key, 0); CdlInterpreter interp = static_cast<CdlInterpreter>(data); CYG_ASSERT_CLASSC(interp); try { result = (*command)(interp, argc, argv); } catch(std::bad_alloc e) { interp->set_result(CdlParse::construct_diagnostic(interp, "internal error", "", "Out of memory.")); result = TCL_ERROR; } catch(CdlStringException e) { interp->set_result(e.get_message()); result = TCL_ERROR; } catch(...) { CYG_FAIL("Unexpected C++ exception"); interp->set_result(CdlParse::construct_diagnostic(interp, "internal error", "", "Unexpected C++ exception.")); result = TCL_ERROR; } CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::add_command(std::string name, CdlInterpreterCommand command) { CYG_REPORT_FUNCNAME("CdlInterpreter::add_command"); CYG_REPORT_FUNCARG2XV(this, command); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); CYG_CHECK_FUNC_PTRC(command); union { CdlInterpreterCommand command; ClientData data; } x; x.command = command; // Tcl 8.4 involves some incompatible API changes #if (TCL_MAJOR_VERSION > 8) || ((TCL_MAJOR_VERSION == 8) && (TCL_MINOR_VERSION >= 4)) if (0 == Tcl_CreateCommand(tcl_interp, CDL_TCL_CONST_CAST(char*, name.c_str()), &tcl_command_proc, x.data, 0)) { throw std::bad_alloc(); } #else if (0 == Tcl_CreateCommand(tcl_interp, CDL_TCL_CONST_CAST(char*, name.c_str()), (int (*)(ClientData,Tcl_Interp*, int, char*[])) &tcl_command_proc, x.data, 0)) { throw std::bad_alloc(); } #endif CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // Remove a command from an interpreter. This is just a wrapper for the // Tcl_DeleteCommand() routine. void CdlInterpreterBody::remove_command(std::string name) { CYG_REPORT_FUNCNAME("CdlInterpreter::remove_command"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); if (0 != Tcl_DeleteCommand(tcl_interp, CDL_TCL_CONST_CAST(char*, name.c_str()))) { CYG_FAIL("attempt to delete non-existant command"); } CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // It is also possible to add and remove whole sets of commands in one go, // keeping track of the current set. std::vector<CdlInterpreterCommandEntry>* CdlInterpreterBody::push_commands(std::vector<CdlInterpreterCommandEntry>& new_commands) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::push_commands", "result %p"); CYG_REPORT_FUNCARG2XV(this, &new_commands); CYG_PRECONDITION_THISC(); std::vector<CdlInterpreterCommandEntry>* result = current_commands; std::vector<CdlInterpreterCommandEntry>::iterator i; // First uninstall all the old commands, if any if (0 != current_commands) { for (i = current_commands->begin(); i != current_commands->end(); i++) { remove_command(i->name); } } // Now install the new commands for (i = new_commands.begin(); i != new_commands.end(); i++) { add_command(i->name, i->command); } // Remember the current set in case of a subsequent push operation current_commands = &new_commands; CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::pop_commands(std::vector<CdlInterpreterCommandEntry>* original_commands) { CYG_REPORT_FUNCNAME("CdlInterpreter::pop_commands"); CYG_REPORT_FUNCARG2XV(this, &original_commands); CYG_PRECONDITION_THISC(); CYG_PRECONDITION(0 != current_commands, "no pop without a previous push please"); std::vector<CdlInterpreterCommandEntry>::iterator i; // Uninstall the most recent set of commands for (i = current_commands->begin(); i != current_commands->end(); i++) { remove_command(i->name); } // Reinstall the previous set, if any if (0 != original_commands) { for (i = original_commands->begin(); i != original_commands->end(); i++) { add_command(i->name, i->command); } } current_commands = original_commands; CYG_REPORT_RETURN(); } std::vector<CdlInterpreterCommandEntry>* CdlInterpreterBody::get_pushed_commands() const { CYG_REPORT_FUNCNAME("CdlInterpreter::get_pushed_commands"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_REPORT_RETURN(); return current_commands; } //}}} //{{{ CdlInterpreter:: variables // ---------------------------------------------------------------------------- // Provide some more stubs, this time for accessing Tcl global variables. void CdlInterpreterBody::set_variable(std::string name, std::string value) { CYG_REPORT_FUNCNAME("CdlInterpreter::set_variable"); CYG_REPORT_FUNCARG2("this %p, name %s", this, name.c_str()); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); if (0 == Tcl_SetVar(tcl_interp, CDL_TCL_CONST_CAST(char*, name.c_str()), CDL_TCL_CONST_CAST(char*, value.c_str()), TCL_GLOBAL_ONLY)) { throw std::bad_alloc(); } CYG_REPORT_RETURN(); } void CdlInterpreterBody::unset_variable(std::string name) { CYG_REPORT_FUNCNAME("CdlInterpreter::unset_variable"); CYG_REPORT_FUNCARG2("this %p, name %s", this, name.c_str()); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); Tcl_UnsetVar(tcl_interp, CDL_TCL_CONST_CAST(char*, name.c_str()), TCL_GLOBAL_ONLY); CYG_REPORT_RETURN(); } std::string CdlInterpreterBody::get_variable(std::string name) { CYG_REPORT_FUNCNAME("CdlInterpreter::get_variable"); CYG_REPORT_FUNCARG2("this %p, name %s", this, name.c_str()); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); std::string result = ""; const char *tmp = Tcl_GetVar(tcl_interp, CDL_TCL_CONST_CAST(char*, name.c_str()), TCL_GLOBAL_ONLY); if (0 != tmp) { result = tmp; } CYG_REPORT_RETURN(); return result; } //}}} //{{{ CdlInterpreter:: assoc data // ---------------------------------------------------------------------------- // Associated data. It is useful to be able to store some C++ data with // Tcl interpreters, so that the implementations of various commands // can retrieve details of the current state. Tcl provides the necessary // underlying support via routines Tcl_SetAssocData() etc., and the // routines here are just stubs for the underlying Tcl ones. void CdlInterpreterBody::set_assoc_data(const char* key, ClientData data, Tcl_InterpDeleteProc* del_proc) { CYG_REPORT_FUNCNAME("CdlInterpreter::set_assoc_data"); CYG_REPORT_FUNCARG3("this %p, key %s, data %p", this, key, data); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC((0 != key) && ('\0' != key[0])); Tcl_SetAssocData(tcl_interp, CDL_TCL_CONST_CAST(char*, key), del_proc, data); CYG_REPORT_RETURN(); } ClientData CdlInterpreterBody::get_assoc_data(const char* key) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::get_assoc_data", "result %p"); CYG_REPORT_FUNCARG2("this %p, key %s", this, key); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC((0 != key) && ('\0' != key[0])); ClientData result = Tcl_GetAssocData(tcl_interp, CDL_TCL_CONST_CAST(char*, key), 0); CYG_REPORT_RETVAL(result); return result; } void CdlInterpreterBody::delete_assoc_data(const char* key) { CYG_REPORT_FUNCNAME("CdlInterpreter::delete_assoc_data"); CYG_REPORT_FUNCARG2("this %p, key %s", this, key); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC((0 != key) && ('\0' != key[0])); Tcl_DeleteAssocData(tcl_interp, CDL_TCL_CONST_CAST(char*, key)); CYG_REPORT_RETURN(); } //}}} //{{{ CdlInterpreter:: file I/O // ---------------------------------------------------------------------------- // Tcl provides file I/O facilities that are already known to be portable // to the platforms of interest. bool CdlInterpreterBody::is_directory(std::string name) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::is_directory", "result %d"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); bool result = false; std::string command = "file isdirectory \"" + name + "\""; std::string tcl_result; if ((TCL_OK == this->eval(command, tcl_result)) && ("1" == tcl_result)) { result = true; } CYG_REPORT_RETVAL(result); return result; } bool CdlInterpreterBody::is_file(std::string name) { CYG_REPORT_FUNCNAMETYPE("CdlInterpreter::is_file", "result %d"); CYG_REPORT_FUNCARG1XV(this); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != name); bool result = false; std::string command = "file isfile \"" + name + "\""; std::string tcl_result; if ((TCL_OK == this->eval(command, tcl_result)) && ("1" == tcl_result)) { result = true; } CYG_REPORT_RETVAL(result); return result; } // ---------------------------------------------------------------------------- void CdlInterpreterBody::locate_subdirs(std::string directory, std::vector<std::string>& result) { CYG_REPORT_FUNCNAME("CdlInterpreter::locate_subdirs"); CYG_REPORT_FUNCARG2XV(this, &result); CYG_PRECONDITION_THISC(); static char locate_subdirs_script[] = "\ set pattern [file join \"$::cdl_locate_subdirs_path\" * .] \n\ set result {} \n\ foreach entry [glob -nocomplain -- $pattern] { \n\ set entry [file tail [file dirname $entry]] \n\ if {($entry != \"CVS\") && ($entry != \"cvs\")} { \n\ lappend result $entry \n\ } \n\ } \n\ return $result \n\ "; std::string tcl_result = ""; set_variable("::cdl_locate_subdirs_path", directory); if (TCL_OK != eval(locate_subdirs_script, tcl_result)) { CYG_FAIL("Internal error evaluating Tcl script"); } int count; const char** array; if (TCL_OK != Tcl_SplitList(tcl_interp, CDL_TCL_CONST_CAST(char*, tcl_result.c_str()), &count, CDL_TCL_CONST_CAST(char***, &array))) { throw std::bad_alloc(); } for (int i = 0; i < count; i++) { result.push_back(array[i]); } Tcl_Free((char*) array); CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // Locating all subdirs requires some simple recursion void CdlInterpreterBody::locate_all_subdirs(std::string directory, std::vector<std::string>& result) { CYG_REPORT_FUNCNAME("CdlInterpreter::locate_all_subdirs"); CYG_REPORT_FUNCARG2XV(this, &result); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != directory); std::vector<std::string> subdirs; locate_subdirs(directory, subdirs); std::vector<std::string>::const_iterator i, j; for (i = subdirs.begin(); i != subdirs.end(); i++) { result.push_back(*i); std::vector<std::string> its_subdirs; locate_all_subdirs(directory + "/" + *i, its_subdirs); for (j = its_subdirs.begin(); j != its_subdirs.end(); j++) { result.push_back(*i + "/" + *j); } } CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // Locating the files in a particular subdirectory. This requires another // simple Tcl script. void CdlInterpreterBody::locate_files(std::string directory, std::vector<std::string>& result) { CYG_REPORT_FUNCNAME("CdlInterpreter::locate_files"); CYG_REPORT_FUNCARG2XV(this, &result); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != directory); static char locate_files_script[] = "\ set pattern [file join \"$::cdl_locate_files_path\" *] \n\ set result {} \n\ foreach entry [glob -nocomplain -- $pattern] { \n\ if ([file isdirectory $entry]) { \n\ continue \n\ } \n\ lappend result [file tail $entry] \n\ } \n\ return $result \n\ "; std::string tcl_result; set_variable("::cdl_locate_files_path", directory); if (TCL_OK != eval(locate_files_script, tcl_result)) { CYG_FAIL("Internal error evaluating Tcl script"); } int count; const char** array; if (TCL_OK != Tcl_SplitList(tcl_interp, CDL_TCL_CONST_CAST(char*, tcl_result.c_str()), &count, CDL_TCL_CONST_CAST(char***, &array))) { throw std::bad_alloc(); } for (int i = 0; i < count; i++) { result.push_back(array[i]); } Tcl_Free((char*) array); CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // Locating all files can be achieved by combining locate_all_subdirs() // and locate_files(). void CdlInterpreterBody::locate_all_files(std::string directory, std::vector<std::string>& result) { CYG_REPORT_FUNCNAME("CdlInterpreter::locate_all_files"); CYG_REPORT_FUNCARG2XV(this, &result); CYG_PRECONDITION_THISC(); CYG_PRECONDITIONC("" != directory); std::vector<std::string> files; std::vector<std::string>::const_iterator i, j; locate_files(directory, files); for (i = files.begin(); i != files.end(); i++) { result.push_back(*i); } std::vector<std::string> all_subdirs; locate_all_subdirs(directory, all_subdirs); for (i = all_subdirs.begin(); i != all_subdirs.end(); i++) { std::vector<std::string> subdir_files; locate_files(directory + "/" + *i, subdir_files); for (j = subdir_files.begin(); j != subdir_files.end(); j++) { result.push_back(*i + "/" + *j); } } CYG_REPORT_RETURN(); } // ---------------------------------------------------------------------------- // Write some data to a file, throwing an I/O exception on failure. This // functionality is needed whenever savefile data is generated, it is // convenient to have a utility function to do the job. Also, performing // the Tcl_Write involves passing const data as a non-const argument: // if this ever causes problems in future it is a good idea to isolate // the problem here. void CdlInterpreterBody::write_data(Tcl_Channel chan, std::string data) { CYG_REPORT_FUNCNAME("CdlInterpreter::write_data"); CYG_REPORT_FUNCARG2XV(this, chan); CYG_PRECONDITION_THISC(); if (-1 == Tcl_Write(chan, CDL_TCL_CONST_CAST(char*, data.data()), data.size())) { std::string msg = "Unexpected error writing to file " + this->get_context() + " : " + Tcl_PosixError(tcl_interp); throw CdlInputOutputException(msg); } CYG_REPORT_RETURN(); } //}}} //{{{ CdlInterpreter:: quote() etc. // ---------------------------------------------------------------------------- // Given a string, quote it in such a way that the Tcl interpreter will // process it as a single word, but keep the result as human-readable // as possible. If there are no special characters then just return the // string itself. Otherwise quoting is necessary. // // The choice is between braces and double quotes. Generally braces // are better and more consistent, but there is a problem if the // string argument itself contains braces. These could be // backslash-escaped, but the Tcl interpreter will not automatically // remove the backslashes so we would end up with a discrepancy // between the original data and what is seen by the parser. In this // case quote marks have to be used instead. // // NOTE: this code may not behave sensibly when it comes to i18n // issues. std::string CdlInterpreterBody::quote(std::string src) { CYG_REPORT_FUNCNAME("CdlInterpreter::quote"); std::string result = ""; bool contains_specials = false; unsigned int i; if (0 == src.size()) { // An empty string. The best way to represent this is an empty // set of quotes. result = "\"\""; CYG_REPORT_RETURN(); return result; } if ('#' == src[0]) { contains_specials = true; } for (i = 0; (i < src.size()) && !contains_specials; i++) { if (isspace(src[i])) { contains_specials = true; break; } switch(src[i]) { case '{': case '}': case '\\': case '$': case '"': case '[': case ']': case '#': case ';': contains_specials = true; break; default: break; } } if (!contains_specials) { result = src; } else{ // If the data is a multiline item, it is better to start it in column 0. // Unfortunately there is the question of what to do with the opening // quote. Putting it on the current line, followed by a backslash-escaped // newline, introduces a space into the string. If the string begins with // a space anyway then arguably this would be harmless, but it could // be confusing to the user. Putting the opening double quote into column 0 // means that the first line of data is indented relative to the rest of // the data, but still appears to be the best alternative. if (src.find('\n') != std::string::npos) { result += "\\\n"; } result += '\"'; for (i = 0; i < src.size(); i++) { switch(src[i]) { case '\\': case '$': case '"': case '[': case ']': result += '\\'; result += src[i]; break; default: result += src[i]; break; } } result += '\"'; } CYG_REPORT_RETURN(); return result; } // ---------------------------------------------------------------------------- // Given some data which may be multiline, return a string which corresponds // to that data turned into a comment. std::string CdlInterpreterBody::multiline_comment(const std::string& orig, int first_indent, int second_indent) { CYG_REPORT_FUNCNAME("CdlInterpreter::multiline_comment"); std::string indent = std::string(first_indent, ' ') + "# " + std::string(second_indent, ' '); std::string result = ""; bool indent_needed = true; std::string::const_iterator str_i; for (str_i = orig.begin(); str_i != orig.end(); str_i++) { if (indent_needed) { result += indent; indent_needed = false; } result += *str_i; if ('\n' == *str_i) { indent_needed = true; } } CYG_REPORT_RETURN(); return result; } // ---------------------------------------------------------------------------- // Given some data, append it to the current line and add additional commented // and indented lines as required. std::string CdlInterpreterBody::extend_comment(const std::string& orig, int first_indent, int second_indent) { CYG_REPORT_FUNCNAME("CdlInterpreter::extend_comment"); std::string indent = std::string(first_indent, ' ') + "# " + std::string(second_indent, ' '); std::string result = ""; bool indent_needed = false; std::string::const_iterator str_i; for (str_i = orig.begin(); str_i != orig.end(); str_i++) { if (indent_needed) { result += indent; indent_needed = false; } result += *str_i; if ('\n' == *str_i) { indent_needed = true; } } CYG_REPORT_RETURN(); return result; } //}}}
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