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@ -139,19 +139,21 @@ corresponds to his/her privileges. There are user groups reflecting the
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structure of lectured courses.
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structure of lectured courses.
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A database of exercises (algorithmic problems) is another part of the project.
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A database of exercises (algorithmic problems) is another part of the project.
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Each exercise consists of a text describing the problem in multiple language
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Each exercise consists of a text describing the problem (optionally in two
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variants, an evaluation configuration (machine-readable instructions on how to
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language variants -- Czech and English), an evaluation configuration
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evaluate solutions to the exercise) and a set of inputs and reference outputs.
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(machine-readable instructions on how to evaluate solutions to the exercise) and
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Exercises are created by instructed privileged users. Assigning an exercise to a
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a set of inputs and reference outputs. Exercises are created by instructed
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group means choosing one of the available exercises and specifying additional
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privileged users. Assigning an exercise to a group means choosing one of the
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properties: a deadline (optionally a second deadline), a maximum amount of
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available exercises and specifying additional properties: a deadline (optionally
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points, a configuration for calculating the score, a maximum number of
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a second deadline), a maximum amount of points, a configuration for calculating
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submissions, and a list of supported runtime environments (e.g. programming
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the score, a maximum number of submissions, and a list of supported runtime
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languages) including specific time and memory limits for each one.
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environments (e.g. programming languages) including specific time and memory
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limits for each one.
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Typical use cases for supported user roles are following:
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Typical use cases for supported user roles are following:
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- **student**
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- **student**
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- create new user account via registration form
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- join a group
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- join a group
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- get assignments in group
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- get assignments in group
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- submit solution to assignment -- upload one source file and trigger
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- submit solution to assignment -- upload one source file and trigger
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@ -180,10 +182,10 @@ students. Concepts of consecutive steps from source code to final results
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is described in more detail below to give readers solid overview of what have to
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is described in more detail below to give readers solid overview of what have to
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happen during evaluation process.
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happen during evaluation process.
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First thing users have to do is to submit their solutions through web user
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First thing students have to do is to submit their solutions through web user
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interface. The system checks assignment invariants (deadlines, count of
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interface. The system checks assignment invariants (deadlines, count of
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submissions, ...) and stores the submitted file. The runtime environment is
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submissions, ...) and stores the submitted code. The runtime environment is
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automatically detected based on input file and a suitable evaluation
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automatically detected based on input file extension and a suitable evaluation
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configuration variant is chosen (one exercise can have multiple variants, for
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configuration variant is chosen (one exercise can have multiple variants, for
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example C and Java languages). This exercise configuration is then used for
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example C and Java languages). This exercise configuration is then used for
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taking care of evaluation process.
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taking care of evaluation process.
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@ -449,20 +451,18 @@ restarted.
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At this point there is a clear idea how the new system will be used and what are
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At this point there is a clear idea how the new system will be used and what are
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the major enhancements for future releases. With this in mind, the overall
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the major enhancements for future releases. With this in mind, the overall
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architecture can be sketched. From the previous research, several goals are set
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architecture can be sketched. To sum up, here is a list of key features of the
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up for the new project. They mostly reflect drawbacks of the current version of
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new system. They come from previous research of current system's drawbacks,
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CodEx and some reasonable wishes of university users. Most notable features are
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reasonable wishes of university users and our major design choices.
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following:
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- modern HTML5 web frontend written in JavaScript using a suitable framework
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- modern HTML5 web frontend written in JavaScript using a suitable framework
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- REST API implemented in PHP, communicating with database, evaluation backend
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- REST API communicating with database, evaluation backend and a file server
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and a file server
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- evaluation backend implemented as a distributed system on top of a message
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- evaluation backend implemented as a distributed system on top of a message
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queue framework (ZeroMQ) with master-worker architecture
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queue framework with master-worker architecture
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- multi-platform worker supporting Linux and Windows environment (latter
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- multi-platform worker supporting Linux and Windows environment (latter
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without sandbox, no general purpose suitable tool available yet)
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without sandbox, no general purpose suitable tool available yet)
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- evaluation procedure configured in a YAML file, compound of small tasks
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- evaluation procedure configured in a human readable text file, compound of
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connected into an arbitrary oriented acyclic graph
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small tasks connected into an arbitrary oriented acyclic graph
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The reasons supporting these decisions are explained in the rest of analysis
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The reasons supporting these decisions are explained in the rest of analysis
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chapter. Also a lot of smaller design choices are mentioned including possible
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chapter. Also a lot of smaller design choices are mentioned including possible
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@ -532,18 +532,18 @@ is implemented. The relative value is set in percents and is called threshold.
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Our university has a few partner grammar schools. There were an idea, that they
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Our university has a few partner grammar schools. There were an idea, that they
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could use CodEx for teaching informatics classes. To make the setup simple for
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could use CodEx for teaching informatics classes. To make the setup simple for
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them, all the software and hardware would be provided by university and hosted
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them, all the software and hardware would be provided by the university as a
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in their datacentre. However, CodEx were not prepared to support this kind of
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completely ready-to-use remote service. However, CodEx were not prepared to
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usage and no one had time to manage a separate instance. With ReCodEx it is
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support this kind of usage and no one had time to manage a separate instance.
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possible to offer hosted environment as a service to other subjects. The concept
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With ReCodEx it is possible to offer hosted environment as a service to other
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we figured out is based on user and group separation inside the system. There
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subjects. The concept we figured out is based on user and group separation
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are multiple _instances_ in the system, which means unit of separation. Each
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inside the system. There are multiple _instances_ in the system, which means
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instance has own set of users and groups, exercises can be optionally shared.
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unit of separation. Each instance has own set of users and groups, exercises can
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Evaluation backend is common for all instances. To keep track of active
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be optionally shared. Evaluation backend is common for all instances. To keep
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instances and paying customers, each instance must have a valid _licence_ to
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track of active instances and paying customers, each instance must have a valid
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allow users submit their solutions. licence is granted for defined period of
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_licence_ to allow users submit their solutions. licence is granted for defined
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time and can be revoked in advance if the subject do not keep approved terms and
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period of time and can be revoked in advance if the subject do not keep approved
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conditions.
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terms and conditions.
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The main work for the system is to evaluate programming exercises. The exercise
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The main work for the system is to evaluate programming exercises. The exercise
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is quite similar to homework assignment during school labs. When a homework is
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is quite similar to homework assignment during school labs. When a homework is
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@ -561,36 +561,6 @@ for every assignment of the same exercise. This separation is natural for all
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users, in CodEx it is implemented in similar way and no other considerable
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users, in CodEx it is implemented in similar way and no other considerable
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solution was found.
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solution was found.
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### Forgotten password
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With authentication and some sort of dealing with passwords is related a problem
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with forgotten credentials, especially passwords. People easily forget them and
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there has to be some kind of mechanism to retrieve a new password or change the
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old one. Problem is that it cannot be done in totally secure way, but we can at
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least come quite close to it. First, there are absolutely not secure and
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recommendable ways how to handle that, for example sending the old password
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through email. A better, but still not secure solution is to generate a new one
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and again send it through email. This solution was provided in CodEx, users had
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to write an email to administrator, who generated a new password and sent it
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back to the sender. This simple solution could be also automated, but
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administrator had quite a big control over whole process. This might come in
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handy if there could be some additional checkups for example, but on the other
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hand it can be quite time consuming.
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Probably the best solution which is often used and is fairly secure is
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following. Let us consider only case in which all users have to fill their
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email addresses into the system and these addresses are safely in the hands of
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the right users. When user finds out that he/she does not remember a password,
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he/she requests a password reset and fill in his/her unique identifier; it might
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be email or unique nickname. Based on matched user account the system generates
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unique access token and sends it to user via email address. This token should be
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time limited and usable only once, so it cannot be misused. User then takes the
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token or URL address which is provided in the email and go to the system's
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appropriate section, where new password can be set. After that user can sign in
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with his/her new password. As previously stated, this solution is quite safe and
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user can handle it on its own, so administrator does not have to worry about it.
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That is the main reason why this approach was chosen to be used.
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### Evaluation unit executed by ReCodEx
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### Evaluation unit executed by ReCodEx
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|
One of the bigger requests for the new system is to support a complex
|
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One of the bigger requests for the new system is to support a complex
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@ -623,14 +593,23 @@ so no sandbox needs to be used as in external tasks case.
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For a job evaluation, the tasks needs to be executed sequentially in a specified
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For a job evaluation, the tasks needs to be executed sequentially in a specified
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order. The idea of running independent tasks in parallel is bad because exact
|
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order. The idea of running independent tasks in parallel is bad because exact
|
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|
time measurement needs controlled environment on target computer with
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time measurement needs controlled environment on target computer with
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|
minimization of interrupts by other processes. It seems that connecting tasks
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minimization of interrupts by other processes. It would be possible to run tasks
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into directed acyclic graph (DAG) can handle all possible problem cases. None of
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which does not need exact time measuremet in parallel, but in this case a
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the authors, supervisors and involved faculty staff can think of a problem that
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synchronization mechanism has to be developed to exclude paralellism for
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cannot be decomposed into tasks connected in a DAG. The goal of evaluation is
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measured tasks. Usually, there are about four times more unmeasured tasks than
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|
to satisfy as many tasks as possible. During execution there are sometimes
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tasks with time measurement, but measured tasks tends to be much longer. With
|
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|
multiple choices of next task. To control that, each task can have a priority,
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[Amdahl's law](https://en.wikipedia.org/wiki/Amdahl's_law) in mind, the
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|
which is used as a secondary ordering criterion. For better understanding, here
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|
|
parallelism seems not to provide a huge benefit in overall execution speed and
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|
is a small example.
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|
brings troubles with synchronization. However, it there will be speed issues,
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this approach could be reconsiderred.
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It seems that connecting tasks into directed acyclic graph (DAG) can handle all
|
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possible problem cases. None of the authors, supervisors and involved faculty
|
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staff can think of a problem that cannot be decomposed into tasks connected in a
|
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DAG. The goal of evaluation is to satisfy as many tasks as possible. During
|
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execution there are sometimes multiple choices of next task. To control that,
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each task can have a priority, which is used as a secondary ordering criterion.
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For better understanding, here is a small example.
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|
![Task serialization](https://github.com/ReCodEx/wiki/raw/master/images/Assignment_overview.png)
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|
![Task serialization](https://github.com/ReCodEx/wiki/raw/master/images/Assignment_overview.png)
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@ -639,20 +618,34 @@ _CompileA_ task is finished, the _RunAA_ task is started (or _RunAB_, but should
|
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|
be deterministic by position in configuration file -- tasks stated earlier
|
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|
be deterministic by position in configuration file -- tasks stated earlier
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|
should be executed earlier). The task priorities guaranties, that after
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|
should be executed earlier). The task priorities guaranties, that after
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_CompileA_ task all dependent tasks are executed before _CompileB_ task (they
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_CompileA_ task all dependent tasks are executed before _CompileB_ task (they
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|
have higher priority number). For example this is useful to control which files
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|
have higher priority number). To sum up, connection of tasks represents
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|
are present in a working directory at every moment. To sum up, there are 3
|
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|
dependencies and priorities can be used to order unrelated tasks and with this
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|
ordering criteria: dependencies, then priorities and finally position of task in
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|
provide a total ordering of them. For well written jobs the priorities may not
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configuration. Together, they define a unambiguous linear ordering of all tasks.
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be so useful, but they can help control execution order for example to avoid
|
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|
situation, where each test of the job generates large temporary file and there
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is a one valid execution order which keeps all the temporary files for later
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processing at one time. Better approach is to finish execution of one test,
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clean the big temporary file and proceed with following test. If there is an
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ambiguity in task ordering at this point, they are executed in order of input
|
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task configuration.
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The total linear ordering of tasks can be done easier with just executing them
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in order of input configuration. But this structure cannot handle well cases,
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|
when a task fails. There is not a easy and nice way how to tell which task
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|
should be executed next. However, this issue can be solved with graph structured
|
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|
dependencies of the tasks. In graph structure, it is clear that all dependent
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tasks has to be skipped and continue execution with a non related task. This is
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the main reason, why the tasks are connected in a DAG.
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For grading there are several important tasks. First, tasks executing submitted
|
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For grading there are several important tasks. First, tasks executing submitted
|
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|
code need to be checked for time and memory limits. Second, outputs of judging
|
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|
code need to be checked for time and memory limits. Second, outputs of judging
|
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|
tasks need to be checked for correctness (represented by return value or by data
|
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|
tasks need to be checked for correctness (represented by return value or by data
|
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|
on standard output) and should not fail on time or memory limits. This division
|
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|
on standard output) and should not fail. This division can be transparent for
|
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|
|
can be transparent for backend, each task is executed the same way. But frontend
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|
backend, each task is executed the same way. But frontend must know which tasks
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|
|
must know which tasks from whole job are important and what is their kind. It is
|
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|
|
from whole job are important and what is their kind. It is reasonable, to keep
|
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|
|
reasonable, to keep this piece of information alongside the tasks in job
|
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|
|
this piece of information alongside the tasks in job configuration, so each task
|
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|
configuration, so each task can have a label about its purpose. Unlabeled tasks
|
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|
can have a label about its purpose. Unlabeled tasks have an internal type
|
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|
have an internal type _inner_. There are four categories of tasks:
|
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|
_inner_. There are four categories of tasks:
|
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|
- _initiation_ -- setting up the environment, compiling code, etc.; for users
|
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|
- _initiation_ -- setting up the environment, compiling code, etc.; for users
|
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|
|
failure means error in their sources which are not compatible with running it
|
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|
failure means error in their sources which are not compatible with running it
|
|
|
@ -724,29 +717,21 @@ what kind of reward for users solutions should be chosen.
|
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|
|
At first let us focus on all kinds of outputs from executed programs within job.
|
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|
At first let us focus on all kinds of outputs from executed programs within job.
|
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|
|
Out of discussion is that supervisors should be able to view almost all outputs
|
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|
|
Out of discussion is that supervisors should be able to view almost all outputs
|
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|
|
from solutions if they choose them to be visible and recorded. This feature is
|
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|
|
from solutions if they choose them to be visible and recorded. This feature is
|
|
|
|
critical in debugging either whole exercises or users solutions. But should it
|
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|
|
critical in debugging either whole exercises or users solutions. Supervisor
|
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|
|
be default behaviour to record every output? Absolutely not, supervisor should
|
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|
|
should have a choice to turn on preserving the data while the default behaviour
|
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|
|
have a choice to turn it on, but discarding the outputs has to be the default
|
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|
|
is to discard them to keep a file base around whole ReCodEx system in sensible
|
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|
|
option. Even without this functionality a file base around whole ReCodEx system
|
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|
|
limits.
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can become quite large and on top of that outputs from executed programs can be
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sometimes very extensive. Storing this amount of data is inefficient and
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More interesting question is if students should see the logs from execution of
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unnecessary to most of the solutions. However, on supervisor request this
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their solution. Usual approach is to keep these information private because of
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feature should be available.
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possibility of leaking input data. This may lead students to hack their
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solutions to pass just the ReCodEx testing cases instead of properly solving the
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More interesting question is what should regular users see from execution of
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assigned problem. Martin Mareš strongly recommended to use this strategy of
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their solution. Simple answer is of course that they should not see anything
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hiding sensitive data too, so ReCodEx does. One exception are compilation
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which is partly true. Outputs from their programs can be anything and users can
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outputs which can help students a lot during troubleshooting. These logs shall
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somehow analyze inputs or even redirect them to output. So outputs from
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be visible unless the supervisor decides otherwise. Note, that due to lack of
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execution should not be visible at all or under very special circumstances. But
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frontend developers, this feature was not implemented in the very first release
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that is not so straightforward for compilation or other kinds of initiation,
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of ReCodEx, but will be definitely available in the future.
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where it really depends on the particular case. Generally it is quite harmless
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to display user some kind of compilation error which can help a lot during
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troubleshooting. Of course again this kind of functionality should be
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configurable by supervisors and disabled by default. There is also the last kind
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of tasks which can output some information which is evaluation tasks. Output of
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these tasks is somehow important to whole system and again can contain some
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information about inputs or reference outputs. So outputs of evaluation tasks
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should not be visible to regular users too.
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The overall concept of grading solutions was presented earlier. To briefly
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The overall concept of grading solutions was presented earlier. To briefly
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remind that, backend returns only exact measured values (used time and memory,
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remind that, backend returns only exact measured values (used time and memory,
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@ -799,7 +784,7 @@ factor. There are several ways how to save structured data:
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- relational database
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- relational database
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Another important factor is amount and size of stored data. Our guess is about
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Another important factor is amount and size of stored data. Our guess is about
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1000 users, 100 exercises, 200 assignments per year and 400000 unique solutions
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1000 users, 100 exercises, 200 assignments per year and 200000 unique solutions
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per year. The data are mostly structured and there are a lot of them with the
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per year. The data are mostly structured and there are a lot of them with the
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same format. For example, there is a thousand of users and each one has the same
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same format. For example, there is a thousand of users and each one has the same
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values -- name, email, age, etc. These kind of data are relatively small, name
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values -- name, email, age, etc. These kind of data are relatively small, name
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@ -1449,8 +1434,8 @@ of connection with no message loss.
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### API server
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### API server
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The API server must handle HTTP requests and manage the state of the application
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The API server must handle HTTP requests and manage the state of the application
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in some kind of a database. It must also be able to communicate with the
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in some kind of a database. It must also be able to communicate with the backend
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backend over ZeroMQ.
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over ZeroMQ.
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We considered several technologies which could be used:
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We considered several technologies which could be used:
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@ -1566,6 +1551,36 @@ including generating the signature and signature verification is done through a
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widely used third-party library which lowers the risk of having a bug in the
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widely used third-party library which lowers the risk of having a bug in the
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implementation of this critical security feature.
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implementation of this critical security feature.
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#### Forgotten password
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With authentication and some sort of dealing with passwords is related a problem
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with forgotten credentials, especially passwords. People easily forget them and
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there has to be some kind of mechanism to retrieve a new password or change the
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old one. Problem is that it cannot be done in totally secure way, but we can at
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least come quite close to it. First, there are absolutely not secure and
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recommendable ways how to handle that, for example sending the old password
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through email. A better, but still not secure solution is to generate a new one
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and again send it through email. This solution was provided in CodEx, users had
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to write an email to administrator, who generated a new password and sent it
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back to the sender. This simple solution could be also automated, but
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administrator had quite a big control over whole process. This might come in
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handy if there could be some additional checkups for example, but on the other
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hand it can be quite time consuming.
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Probably the best solution which is often used and is fairly secure is
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following. Let us consider only case in which all users have to fill their
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email addresses into the system and these addresses are safely in the hands of
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the right users. When user finds out that he/she does not remember a password,
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he/she requests a password reset and fill in his/her unique identifier; it might
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be email or unique nickname. Based on matched user account the system generates
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unique access token and sends it to user via email address. This token should be
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time limited and usable only once, so it cannot be misused. User then takes the
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token or URL address which is provided in the email and go to the system's
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appropriate section, where new password can be set. After that user can sign in
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with his/her new password. As previously stated, this solution is quite safe and
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user can handle it on its own, so administrator does not have to worry about it.
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That is the main reason why this approach was chosen to be used.
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#### Uploading files
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#### Uploading files
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There are two cases when users need to upload files using the API -- submitting
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There are two cases when users need to upload files using the API -- submitting
|
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|