logic issue being worked, "independent test 1" should be throwing an exception with current settings. Is ignoring the throw call.

master
Phanes 2017-12-01 21:41:22 -05:00
parent 19c465bdaf
commit 9e4c88262a
5 changed files with 174 additions and 65 deletions

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@ -2,35 +2,35 @@
"units": [
{
"name": "independent test 1",
"target": "(>&2 echo 'error is a doodle day')",
"rectifier": "/usr/bin/true",
"active": true,
"required": true,
"rectify": true
},
{
"name": "independent test 2",
"target": "/usr/bin/false",
"rectifier": "/usr/bin/true",
"active": true,
"required": true,
"rectify": false
},
{
"name": "independent test 2",
"target": "/usr/bin/false",
"rectifier": "/usr/bin/false",
"active": true,
"required": false,
"rectify": false
},
{
"name": "A DEFINITION THAT IS NOT USED",
"target": "/usr/bin/false",
"rectifier": "/usr/bin/true",
"rectifier": "/usr/bin/false",
"active": true,
"required": true,
"rectify": false
"rectify": true
},
{
"name": "dependent test",
"target": "/usr/bin/false",
"rectifier": "/usr/bin/true",
"rectifier": "/usr/bin/false",
"active": true,
"required": true,
"rectify": false
"rectify": true
}
]
}

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@ -13,6 +13,15 @@ class Task_NotReady: public std::runtime_error { public:
Task_NotReady(): std::runtime_error("Task: Attempted to access a unit of a Task that is not defined.") {}
};
/// Task_RequiredButFailedTask - Exception thrown when a Task is failed but required, and rectification also failed.
class Task_RequiredButFailedTask: public std::runtime_error { public:
Task_RequiredButFailedTask(): std::runtime_error("Task: Attempted to access a unit of a Task that failed, but was required, and the corresponding rectification target also failed..") {}
};
/// Task_RequiredButFailedTask - Exception thrown when a Task is failed but required, and rectification also failed but returned with a zero exit code (dont try to fool the check).
class Task_RequiredButRectifierDoesNotHeal: public std::runtime_error { public:
Task_RequiredButRectifierDoesNotHeal(): std::runtime_error("Task: The rectification script was executed and reported success, but did not actually heal the faulty condition of the Task target.") {}
};
/// Task::Task() - Constructor for the Task class. The Task is the building block of a Plan indicating of which Unit to
/// execute, and its dependencies on other units to have already been completed successfully.
@ -86,33 +95,130 @@ bool Task::has_definition() {
}
/// Task::execute - execute a task's unit definition.
/// See the design document for what flow control needs to look like here.
/// \param verbose - Verbosity level - not implemented yet.
void Task::execute( bool verbose )
{
// throw if unit not coupled
// DUFFING
// PREWORK
// throw if unit not coupled to all necessary values since Task is stateful (stateful is okay)
if (! this->has_definition() ) { throw Task_NotReady(); }
// get the name
std::string task_name = this->definition.get_name();
// END PREWORK
// get the target execution command
std::string target_command = this->definition.get_target();
// if we're in verbose mode, do some verbose things
if ( verbose )
{
std::cout << "\t Using unit \"" << this->definition.get_name() << "\"." << std::endl;
std::cout << "\t Executing target \"" << this->definition.get_target() << "\"." << std::endl;
std::cout << "\tUsing unit \"" << task_name << "\"." << std::endl;
std::cout << "\tExecuting target \"" << target_command << "\"." << std::endl;
}
std::string executionString = this->definition.get_target();
std::string rectifierString = this->definition.get_rectifier();
// execute target
int return_code = Sproc::execute( target_command );
int return_code = Sproc::execute( executionString );
if ( return_code )
// d[0] check exit code of target
if (return_code == 0)
{
std::cout << "Process failed with exit code " << return_code << "." << std::endl;
// Zero d[0] return from target execution, good to return
if ( verbose )
{
std::cout << "\tTarget " << task_name << " succeeded." << std::endl;
}
// next
return;
std::cout << "Performing rectification: " << rectifierString << "." << std::endl;
int rectifier_error = Sproc::execute( rectifierString );
} else {
// Non-Zero d[0] from initial target execution, get to d[1]
std::cout << "\tTarget \"" << task_name << "\" failed with exit code " << return_code << "." << std::endl;
// check if rectify pattern is enabled d[1]
if ( this->definition.get_rectify() )
{
// yes d[1]
std::cout << "\tRectification pattern is enabled for \"" << task_name << "\"." << std::endl;
// execute RECTIFIER
std::string rectifier_command = this->definition.get_rectifier();
std::cout << "\tExecuting rectification: " << rectifier_command << "." << std::endl;
int rectifier_error = Sproc::execute( rectifier_command );
// d[3] check exit code of rectifier
if ( rectifier_error )
{
std::cout << "Designated rectification script failed with error " << rectifier_error << "." << std::endl;
}
//d[3] non-zero
std::cout << "\tRectification of \"" << task_name << "\" failed with exit code " << rectifier_error << "." << std::endl;
// d[2] check if REQUIRED
if ( this->definition.get_required() )
{
// d[2] yes
// halt/exception
throw Task_RequiredButFailedTask();
} else {
// d[2] no
// next
return;
}
} else {
// d[3] zero
// execute target
std::cout << "\tRe-Executing target \"" << this->definition.get_target() << "\"." << std::endl;
int retry_code = Sproc::execute( target_command );
// d[4] exit code of target retry
if (retry_code == 0) {
// d[4] zero
return;
} else {
// d[4] non-zero
// d[5] required check
if ( this->definition.get_required() )
{
// d[5] yes
throw Task_RequiredButRectifierDoesNotHeal();
} else {
// d[5] no
// next
return;
}
}
}
} else {
// no d[1]
std::cout << "\tRectification is not enabled for \"" << task_name << "\"." << std::endl;
// required d[2]
if ( this->definition.get_required() )
{
// d[2] yes
// This is executing.....
std::cout << "\tThis task is required to continue the plan." << std::endl;
// but these are NOT executing?????
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
throw Task_RequiredButFailedTask();
} else {
// d[2] no
std::cout << "\tThis task is not required to continue the plan." << std::endl;
return;
}
}
}
}

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@ -52,13 +52,13 @@ int Unit::load_root(Json::Value loader_root)
{ this->rectifier = loader_root.get("rectifier", errmsg).asString(); } else throw Unit_DataStructureException();
if ( loader_root.isMember("active") )
{ this->active = loader_root.get("active", errmsg).asString(); } else throw Unit_DataStructureException();
{ this->active = loader_root.get("active", errmsg).asBool(); } else throw Unit_DataStructureException();
if ( loader_root.isMember("required") )
{ this->required = loader_root.get("required", errmsg).asString(); } else throw Unit_DataStructureException();
{ this->required = loader_root.get("required", errmsg).asBool(); } else throw Unit_DataStructureException();
if ( loader_root.isMember("rectify") )
{ this->rectify = loader_root.get("rectify", errmsg).asString(); } else throw Unit_DataStructureException();
{ this->rectify = loader_root.get("rectify", errmsg).asBool(); } else throw Unit_DataStructureException();
this->populated = true;
@ -119,7 +119,7 @@ std::string Unit::get_rectifier()
/// Unit::get_active - retrieves the armed status of the unit.
///
/// \return the armed status of the unit.
std::string Unit::get_active()
bool Unit::get_active()
{
if ( ! this->populated ) { throw Unit_NotPopulated(); }
return this->active;
@ -128,7 +128,7 @@ std::string Unit::get_active()
/// Unit::get_required - retrieves the requirement status of the unit.
///
/// \return the requirement status of the unit.
std::string Unit::get_required()
bool Unit::get_required()
{
if ( ! this->populated ) { throw Unit_NotPopulated(); }
return this->required;
@ -137,7 +137,7 @@ std::string Unit::get_required()
/// Unit::get_rectify - retrieves the rectification status of the unit.
///
/// \return the rectification status of the unit.
std::string Unit::get_rectify()
bool Unit::get_rectify()
{
if ( ! this->populated ) { throw Unit_NotPopulated(); }
return this->rectify;

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@ -28,15 +28,15 @@ private:
// an indicator of whether the test is active or not
// this is used as a way to give definers a way to force executors to edit arbitrary fields or prevent
// execution of potentially dangerous or intrusive tests
std::string active;
bool active;
// an indicator of whether or not this test is required to pass.
// intended to be used as a flag to halt execution of further tests on failure
std::string required;
bool required;
// indicator of whether the rectifier executable should be run on test failures.
// if rectifier exits on non-zero return code, it should be trigger the behaviour indicated by required
std::string rectify;
bool rectify;
public:
Unit();
@ -52,9 +52,9 @@ public:
std::string get_target();
std::string get_output();
std::string get_rectifier();
std::string get_active();
std::string get_required();
std::string get_rectify();
bool get_active();
bool get_required();
bool get_rectify();
};
#endif //FTESTS_UNIT_H

View File

@ -7,34 +7,23 @@
/// \param input - The commandline input to execute.
/// \return - The return code of the execution of input in the calling shell.
int Sproc::execute(std::string input) {
std::cout << std::endl << "made it to subprocess execution but not implemented yet" << std::endl << std::endl;
int PIPE_READ = 0;
int PIPE_WRITE = 1;
int stdin_pipe[2];
// int aStderrPipe[2];
int stderr_pipe[2];
int stdout_pipe[2];
int child_pid;
char nChar;
int child_exit_code;
if (pipe(stdin_pipe) < 0)
if ( pipe(stdin_pipe) < 0 )
{
perror("allocating pipe for child input redirect");
return -1;
}
/*
if (pipe(aStderrPipe < 0)) {
close(aStderrPipe[PIPE_READ]);
close(aStderrPipe[PIPE_WRITE]);
perror("allocating pipe for error redirect");
return -1;
}
*/
if (pipe(stdout_pipe) < 0)
if ( pipe(stdout_pipe) < 0 )
{
close(stdin_pipe[PIPE_READ]);
close(stdin_pipe[PIPE_WRITE]);
@ -42,6 +31,14 @@ int Sproc::execute(std::string input) {
return -1;
}
if ( pipe(stderr_pipe) < 0 ) {
close(stderr_pipe[PIPE_READ]);
close(stderr_pipe[PIPE_WRITE]);
perror("allocating pipe for error redirect");
return -1;
}
child_pid = fork();
if (0 == child_pid)
{
@ -58,41 +55,41 @@ int Sproc::execute(std::string input) {
}
// redirect stderr
if (dup2(stdout_pipe[PIPE_WRITE], STDERR_FILENO) == -1) {
if (dup2(stderr_pipe[PIPE_WRITE], STDERR_FILENO) == -1) {
exit(errno);
}
// all these are for use by parent only
close(stdin_pipe[PIPE_READ]);
close(stdin_pipe[PIPE_WRITE]);
close(stdout_pipe[PIPE_READ]);
close(stdout_pipe[PIPE_WRITE]);
close(stderr_pipe[PIPE_READ]);
close(stderr_pipe[PIPE_WRITE]);
// run child process image
// replace this with any exec* function find easier to use ("man exec")
child_exit_code = system( input.c_str() );
// if we get here at all, an error occurred, but we are in the child
// process, so just exit
exit(child_exit_code);
return WEXITSTATUS(child_exit_code);
} else if (child_pid > 0) {
// parent continues here
// close unused file descriptors, these are for child only
close(stdin_pipe[PIPE_READ]);
close(stdout_pipe[PIPE_WRITE]);
// da fuq?
/* // Include error check here
if (NULL != szMessage)
{
write(stdin_pipe[PIPE_WRITE], szMessage, strlen(szMessage));
}
*/
close(stderr_pipe[PIPE_WRITE]);
// Just a char by char read here, you can change it accordingly
while (read(stdout_pipe[PIPE_READ], &nChar, 1) == 1)
while ( read( stdout_pipe[PIPE_READ], &nChar, 1 ) == 1 )
{
// does this loop also need to involve STDERR? -CP
write(STDOUT_FILENO, &nChar, 1);
}
@ -100,12 +97,18 @@ int Sproc::execute(std::string input) {
// open of course as long as you want to talk to the child
close(stdin_pipe[PIPE_WRITE]);
close(stdout_pipe[PIPE_READ]);
close(stderr_pipe[PIPE_READ]);
} else {
// failed to create child
close(stdin_pipe[PIPE_READ]);
close(stdin_pipe[PIPE_WRITE]);
close(stdout_pipe[PIPE_READ]);
close(stdout_pipe[PIPE_WRITE]);
close(stderr_pipe[PIPE_READ]);
close(stderr_pipe[PIPE_WRITE]);
}
return child_exit_code;
return WEXITSTATUS(child_exit_code);
}