C++TESK Quick Reference » History » Revision 4
Revision 3 (Mikhail Chupilko, 09/20/2013 12:56 PM) → Revision 4/8 (Alexander Kamkin, 05/22/2014 10:24 AM)
h1. C++TESK Quick Reference
{{toc}}
h2. Introduction
This document is a quick reference of C++TESK Hardware Extension tool (С++TESK, hereafter) included into C++TESK Testing ToolKit and aimed to automated development of test systems for HDL-models (HDL (Hardware Description Language) — class of program languages used for description of hardware) of hardware. The tool architecture bases on general UniTESK (http://www.unitesk.ru) conventions.
_Test system_ is meant to be a special program which evaluates the functional correctness of _target system_, applying some input data (_stimuli_) and analyzing received results of their application (_reactions_). Typical test system consists of three common components: (1) _stimulus generator_ making sequences of stimuli (_test sequences_), (2) _test oracle_ checking correctness of reactions, and (3) _test completeness evaluator_.
The document describes facilities of C++TESK aimed to development of mentioned test system components, and consists of four common chapters.
* Development of reference model
* Development of reference model adapter
* Description of test coverage
* Development of test scenario
First two chapters touch upon development of test oracle basic parts: _reference model_ covering functionality of target system, and _reference model adapter_ binding reference model with target system. The third chapter is devoted to the test completeness estimation on the base of _test coverage_. The last chapter concerns development of test scenario which is the main part of stimulus generator.
More detailed toolkit review is given in _«C++TESK Testing ToolKit: User Guide»_.
Installation process of C++TESK is described in _«С++TESK Testing ToolKit: Installation Guide»_.
h2. Supporting obsolete constructions
Updates of C++TESK do not interfere in the compilation and running of test systems developed for older versions of C++TESK. When the toolkit has incompatible with older versions update, this update is marked by a build number in form of yymmdd, i.e. 110415 – the 15th of April, 2011. The update is available only if macro CPPTESKHW_VERSION (using gcc compiler it can be done by the option –Dmacro_name=value) is appropriately defined. E.g.,
-DCPPTESKHW_VERSION=110415 enables usage of incompatible updated having been made by the 15th of April, 2011 (including this date). Each build of the toolkit has the whole list of such changes.
Obsolete constructions of the toolkit are not described in this document. Possibilities of the toolkit, being incompatible with having become obsolete constructions, are presented with the build number, since which they have been available. E.g., the sentence “the means are supported from 110415 build” means that usage of these means requires two conditions: (1) using toolkit build has the number 110415 or greater, (2) the compilation option -DCPPTESKHW_VERSION=number, where number is not less than 110415, is used.
If some obsolete constructions are not used or prevent the toolkit from further development, they might become unsupported. In this case, during compilation of test system using these constructions, a message with advices about correction of test system will be shown.
During compilation of test systems, developed by means of C++TESK, usage of the compiler option -DCPPTESKHW_VERSION=number is highly recommended.
h2. Naming convention
The core of the toolkit is developed as a C++ library. Available means are grouped into the following namespaces.
* cpptesk::hw — means for development of reference models and their adapters;
* cpptesk::ts — basic means for test system development;
* cpptesk::ts::coverage — means for test coverage description;
* сpptesk::ts::engine — library with _test engines_ (test engines are toolkit library components used for producing of stimulus sequence, use _test scenario_ (see chapter _“Development of test scenario”_));
* cpptesk::tracer — means for tracing;
* cpptesk::tracer::coverage — means for coverage tracing.
A lot of C++TESK means are implemented in form of macros. To avoid conflicts of names, names of all macros start with prefix CPPTESK_, e.g., CPPTESK_MODEL(name). Generally, each macro has two aliases: shortened name (without CPPTESK_ prefix) and short name, (after additional “compression” of shortened name). E.g., macro CPPTESK_ITERATION_BEGIN has two aliases: ITERATION_BEGIN and IBEGIN. To use shortened and short names, macros CPPTESK_SHORT_NAMES and CPPTESK_SHORT_SHORT_NAMES should be defined, respectively.
h2. Development of reference model
Reference model is a structured set of classes describing functionality of target system at some abstraction level (the toolkit allows developing of both abstract functional models and detailed models describing target system cycle-accurately). Reference model consists of message classes describing format of input and output data (structures of stimuli and reactions), main class and set of auxiliary classes. Hereafter, a main class of reference model will be meant under term reference model.
h3. Class of message
Message classes are declared by macro @CPPTESK_MESSAGE(name)@. Row with macro @CPPTESK_SUPPORT_CLONE(name)@ defining the message clone method @name* clone()@ should be written inside of the each message class declaration.
Example:
<pre><code class="cpp">
#include <hw/message.hpp>
CPPTESK_MESSAGE(MyMessage) {
public:
CPPTESK_SUPPORT_CLONE(MyMessage)
...
};
</code></pre>
*Notice*: Row @CPPTESK_SUPPORT_CLONE(name)@ is obligatory.
h4. Input message randomizer
Virtual method @randomize()@ (randomizer of the message) should be overloaded in each input message class. There are two macros @CPPTESK_{DECLARE|DEFINE}_RANDOMIZER@ for this purpose.
Example:
<pre><code class="cpp">
CPPTESK_MESSAGE(MyMessage) {
...
CPPTESK_DECLARE_RANDOMIZER();
private:
int data;
};
CPPTESK_DEFINE_RANDOMIZER(MyMessage) {
data = CPPTESK_RANDOM(int);
}
</code></pre>
The following macros can be used for randomization of data fields.
* @CPPTESK_RANDOM(type)@ — generation of random integer value;
* @CPPTESK_RANDOM_WIDTH(type, length)@ — generation of random integer value of given number of bits;
* @CPPTESK_RANDOM_FIELD(type, min_bit, max_bit)@ — generation of random integer value with zero bits outside the given range;
* @CPPTESK_RANDOM_RANGE(type, min_value, max_value)@ — generation of random integer value from given integer range;
* @CPPTESK_RANDOM_CHOICE(type, value_1, ..., value_n)@ — random choice from given set of any type values.
*Notice*: randomizer may not be defined if all data fields are defined by special macros (see chapter _“Message data fields”_).
h4. Comparator of output messages
Virtual method @compare()@ (comparator of messages) should be overloaded in each output message class. There are two macro @CPPTESK_{DECLARE|DEFINE}_COMPARATOR@ for this purpose (build is not less than 110428).
Example:
<pre><code class="cpp">
CPPTESK_MESSAGE(MyMessage) {
...
CPPTESK_DECLARE_COMPARATOR();
private:
int data;
};
CPPTESK_DEFINE_COMPARATOR(MyMessage) {
const MyMessage &rhs = CPPTESK_CONST_CAST_MESSAGE(MyMessage);
// in case of difference between messages return not empty string
if(data != rhs.data)
{ return "incorrect data"; }
// empty string is interpreted as absence of difference
return COMPARE_OK;
}
</code></pre>
*Notice*: comparator may not be defined if all data fields are defined by special macros (see chapter “Message data fields”).
h4. Message data fields
The following macros are aimed to declaration of integer data fields.
* @CPPTESK_DECLARE_FIELD(name, length)@ declares integer field with given name and length.
* @CPPTESK_DECLARE_MASKED_FIELD(name, length, mask)@ declares integer field with given name, length, and mask.
* @CPPTESK_DECLARE_BIT(name)@ declares bit field with given name.
Example:
<pre><code class="cpp">
#include <hw/message.hpp>
CPPTESK_MESSAGE(MyMessage) {
public:
CPPTESK_DECLARE_MASKED_FIELD(addr, 32, 0xffffFFF0);
CPPTESK_DECLARE_FIELD(data, 32);
CPPTESK_DECLARE_BIT(flag);
...
};
</code></pre>
*Notice*: length of the data fields should not exceed 64 bits.
All declared data fields should be registered in message class constructor by means of macro @CPPTESK_ADD_FIELD(full_name)@ or, when the data field should not be taken into account by comparator, by means of @CPPTESK_ADD_INCOMPARABLE_FIELD(full_name)@.
Example:
<pre><code class="cpp">
MyMessage::MyMessage() {
CPPTESK_ADD_FIELD(MyMessage::addr);
CPPTESK_ADD_FIELD(MyMessage::data);
CPPTESK_ADD_INCOMPARABLE_FIELD(MyMessage::flag);
...
}
</code></pre>
*Notice*: full_name means usage both name of method and name of class.
h4. Optional messages
Output message can be declared to be optional (not obligatory for receiving) if the following method is used.
<pre><code class="cpp">void setOptional(optional_or_not_optional);</code></pre>
*Notice*: Default value of the parameter “optional_or_not_optional” is true, i.e. if there has not been correspondent implementation output message by a certain timeout, the message will be simply deleted without showing of an error. At the same time, the optional message is added to the interface arbiter and might affect to the matching of other output messages. If correspondent implementation reactions are received after the timeout and they are to be ignored, the flag of the message being optional should be set in message class constructor.
h2. Reference model
Reference model (main class of the reference model) is declared by macro @CPPTESK_MODEL(name)@.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_MODEL(MyModel) {
...
};
</code></pre>
Reference model contains declaration of input and output interfaces, operations, auxiliary processes, and data necessary for operation description.
h3. Interface
Input and output interfaces of the reference model are declared by means of two macros @CPPTESK_DECLARE_{INPUT|OUTPUT}(name)@, respectively.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_MODEL(MyModel) {
public:
CPPTESK_DECLARE_INPUT(input_iface);
CPPTESK_DECLARE_OUTPUT(output_iface);
...
};
</code></pre>
All declared interfaces should be registered in reference model constructor by means of two macros @CPPTESK_ADD_{INPUT|OUTPUT}(name)@.
Example:
<pre><code>
MyModel::MyModel() {
CPPTESK_ADD_INPUT(input_iface);
CPPTESK_ADD_OUTPUT(output_iface);
...
}
</code></pre>
h3. Setting up ignoring of failures on output interface
To disable showing errors of a certain type on a given interface is possible by means of the method:
<pre><code class="cpp">
void setFailureIgnoreTypes(disabling_error_types_mask);
</code></pre>
Disabling error types include errors of implementation reaction absence (@MISSING_REACTION@) and specification reaction absence (@UNEXPECTED_REACTION@) on the given interface. Error types can be grouped by bit operation “or”.
h3. Process
Processes are the main means of functional specification of hardware. Processes are subdivided into operations (see chapter _“Operation”_) and internal processes. Operations describe processing of stimuli of a certain types by the target system. Internal processes are used for definition of the other, more complex processes, including operations.
Declaration and definition of reference model processes are made by means of macros @CPPTESK_{DECLARE|DEFINE}_PROCESS(name)@. Definition of the process should be started by calling macro @CPPTESK_START_PROCESS()@, and finished by calling macro @CPPTESK_STOP_PROCESS()@.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_MODEL(MyModel) {
public:
...
CPPTESK_DECLARE_PROCESS(internal_process);
...
};
CPPTESK_DEFINE_PROCESS(MyModel::internal_process) {
CPPTESK_START_PROCESS();
...
CPPTESK_STOP_PROCESS();
}
</code></pre>
*Notice*: macro @CPPTESK_START_PROCESS()@ may be used only once in definition of the process, and usually precedes the main process code. Semantics of @CPPTESK_STOP_PROCESS()@ is similar to the semantics of operator return — when the macro is called, the process finished.
*Notice*: keyword process is reserved and cannot be used for naming of processes.
h3. Process parameters
Process should have three obligatory parameters: (1) process execution context, (2) associated with process interface, and (3) message. To access process parameters is possible by means of the following macros.
* @CPPTESK_GET_PROCESS()@ — get process context;
* @CPPTESK_GET_IFACE()@ — get process interface;
* @CPPTESK_GET_MESSAGE()@ — get message.
To cast message parameter to the necessary type is possible by means of the following macros.
* @CPPTESK_CAST_MESSAGE(message_class)@;
* @CPPTESK_CONST_CAST_MESSAGE(message_class)@.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_DEFINE_PROCESS(MyModel::internal_process) {
// copy message to the local variable
MyMessage msg = CPPTESK_CAST_MESSAGE(MyMessage);
// get reference to the message
MyMessage &msg_ref = CPPTESK_CAST_MESSAGE(MyMessage);
// get constant reference to the message
const MyMessage &const_msg_ref = CPPTESK_CONST_CAST_MESSAGE(MyMessage);
...
}
</code></pre>
h3. Process priority
During execution, each process is assigned with a priority, unsigned integer value from range @[1, 255]@ (0 is reserved). Priority affects the order of process execution inside of one cycle (processes with higher priority run first). Priorities may be used in matching of implementation and specification reactions (see chapter _“Reaction arbiter”_). When started, all processes are assigned with the same priority (@NORMAL_PRIORITY@). To change the priority is possible by means of the following macros.
* @CPPTESK_GET_PRIORITY()@ — get process priority.
* @CPPTESK_SET_PRIORITY(priority)@ — set process priority.
Some priority values are defined in the enumeration type @priority_t (cpptesk::hw namespace)@. The most general of them are the following ones.
* @NORMAL_PRIORITY@ — normal priority;
* @LOWEST_PRIORITY@ — the lowest priority;
* @HIGHEST_PRIORITY@ — the highest priority.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
#include <iostream>
CPPTESK_DEFINE_PROCESS(MyModel::internal_process) {
...
std::cout << "process priority is " << std::dec
<< CPPTESK_GET_PRIORITY() << std::end;
...
CPPTESK_SET_PRIORITY(cpptesk::hw::HIGHEST_PRIORITY);
...
}
</code></pre>
h3. Modeling of delays
To model delays in processes is possible by means of the following macros.
* @CPPTESK_CYCLE()@ - delay of one cycle.
* @CPPTESK_DELAY(number_of_cycles)@ - delay of several cycles.
* @CPPTESK_WAIT(condition)@ - delay till condition is satisfied.
* @CPPTESK_WAIT_TIMEOUT(condition, timeout)@ - limited in time delay till condition is satisfied.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
#include <iostream>
CPPTESK_DEFINE_PROCESS(MyModel::internal_process) {
...
std::cout << "cycle: " << std::dec << time() << std::end;
// delay of one cycle
CPPTESK_CYCLE();
std::cout << "cycle: " << std::dec << time() << std::end;
...
// wait till outputs.ready is true,
// but not more than 100 cycles
CPPTESK_WAIT_TIMEOUT(outputs.ready, 100);
...
}
</code></pre>
h3. Process calling
Reference model process calling from another process is made by means of macro @CPPTESK_CALL_PROCESS(mode, process_name, interface, message)@, where mode might be either @PARALLEL@ or @SEQUENTIAL@. In the first case separated process is created, which is executed in parallel with the parent process. In the second case consequent execution is performed, where returning to the parent process execution is possible only after child process has been finished.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_DEFINE_PROCESS(MyModel::some_process) {
...
// call separated process
CPPTESK_CALL_PROCESS(PARALLEL, internal_process,
CPPTESK_GET_IFACE(), CPPTESK_GET_MESSAGE());
...
// call process and wait till it has been finished
CPPTESK_CALL_PROCESS(SEQUENTIAL, internal_process,
CPPTESK_GET_IFACE(), CPPTESK_GET_MESSAGE());
...
}
</code></pre>
*Notice*: to call new processes is possible from any reference model methods, not only from methods describing processes. Macro @CPPTESK_CALL_PARALLEL(process_name, interface, message)@ should be used in this case. Calling process with mode @SEQUENTIAL@ from the method not being a process is prohibited.
h3. Stimulus receiving
Inside of the process, receiving of stimulus on one of the input interfaces can be modeled. It is possible by means of macro @CPPTESK_RECV_STIMULUS(mode, interface, message)@. Executing this macro, test system applies the stimulus to the target system via adapter of the correspondent input interface (see chapter _«Input interface adapter»_). Semantics of the mode parameter is described in the chapter _«Process calling»_.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_DEFINE_PROCESS(MyModel::some_process) {
// modeling of stimulus receiving
CPPTESK_RECV_STIMULUS(PARALLEL, input_iface, input_msg);
...
}
</code></pre>
h3. Reaction sending
Modeling of reaction sending is done by the macro @CPPTESK_SEND_REACTION(mode, interface, message)@. Executing this macro, test system calls adapter of the correspondent output interface. The adapter starts waiting for the proper implementation reaction. When being received, the reaction is transformed into object of the correspondent message class (see chapter _“Adapter of the output interface”_). Then test system compares reference message with received message by means of comparator (see chapter _“Comparator of output messages”_). Semantics of the mode parameter is described in the chapter _“Process calling”_.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_DEFINE_PROCESS(MyModel::some_process) {
// modeling of reaction sending
CPPTESK_SEND_REACTION(SEQUENTIAL, output_iface, output_msg);
...
}
</code></pre>
h3. Operation
Declaration and definition of interface operations of reference model is made by means of macros @CPPTESK_{DECLARE|DEFINE}_STIMULUS(name)@. The definition should start from macro @CPPTESK_START_STIMULUS(mode)@, and stop by macro @CPPTESK_STOP_STIMULUS()@.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_MODEL(MyModel) {
public:
CPPTESK_DECLARE_STIMULUS(operation);
...
};
CPPTESK_DEFINE_STIMULUS(MyModel::operation) {
CPPTESK_START_STIMULUS(PARALLEL);
...
CPPTESK_STOP_STIMULUS();
}
</code></pre>
*Notice*: operations are particular cases of processes, so that all the constructions from chapter _“Process”_ can be used in them.
*Notice*: calling macro @CPPTESK_START_STIMULUS(mode)@ is equivalent to the calling macro @CPPTESK_RECV_STIMULUS(mode, ...)@, where interface and message parameters are assigned with correspondent operation parameters.
h3. Callback function
In the main class of reference model, several callback functions are defined. The functions can be overloaded in the reference model. The main callback function is @onEveryCycle()@.
h4. Function onEveryCycle
Function @onEveryCycle()@ is called at the beginning of each reference model execution cycle.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_MODEL(MyModel) {
public:
virtual void onEveryCycle();
...
};
void MyModel::onEveryCycle() {
std::cout << "onEveryCycle: time=" << std::dec << time() << std::endl;
}
</code></pre>
h2. Development of reference model adapter
_Reference model adapter_ (_mediator_) is a component of test system, binding reference model with target system. The adapter _serializes_ input message objects into sequences of input signal values, _deserializes_ sequences of output signal values into output message objects, and matches received from target system reactions with reference values.
h3. Reference model adapter
Reference model adapter is a subclass of reference model class. It is declared by means of the macro @CPPTESK_ADAPTER(adapter_name, model_name)@.
Example:
<pre><code class="cpp">
#include <hw/media.hpp>
CPPTESK_ADAPTER(MyAdapter, MyModel) {
...
};
</code></pre>
_Synchronization methods_, _input_ and _output interface adapters_, _output interface listeners_, and _reaction arbiters_ are declared in reference model adapter.
h4. Synchronizer
Synchronizer is a low-level part of reference model adapter, responsible for synchronization of test system with being tested HDL-model. Synchronizer is implemented by overloading the following five methods of reference model adapter.
* @void initialize()@ — test system initialization;
* @void finialize()@ — test system finalization;
* @void setInputs()@ — synchronization of inputs;
* @void getOutputs()@ — synchronization of outputs;
* @void simulate()@ — synchronization of time.
When hardware models written in Verilog being verified, these methods can be implemented by standard interface VPI (Verilog Procedural Interface). Also, tool VeriTool (http://forge.ispras.ru/projects/veritool) can be used for automation of synchronizer development. In this case, macro @CPPTESK_VERITOOL_ADAPTER(adapter_name, model_name)@ can be used for facilitating of the efforts.
Example:
<pre><code class="cpp">
#include <hw/veritool/media.hpp>
// file generated by tool VeriTool
#include <interface.h>
CPPTESK_VERITOOL_ADAPTER(MyAdapter, MyModel) {
...
};
</code></pre>
Used for definition of synchronization methods functions and data structures (fields inputs and outputs) are generated automatically by tool VeriTool analyzing Verilog hardware model interface.
*Notice*: when macro @CPPTESK_VERITOOL_ADAPTER@ being used, fields inputs и outputs should not be declared and methods and methods of synchronizer should not be overloaded.
*Notice*: tool VeriTool provides access to values of all HDL-model signals, including internal ones. To get access is possible by means of macros @CPPTESK_GET_SIGNAL(signal_type, signal_name)@ for getting value of signal @testbench.target.signal_name@ (@signal_type@ is meant to be from the following list: int, uint64_t, etc.), and @CPPTESK_SET_SIGNAL(signal_type, signal_name, new_value)@ for setting to a new value the signal @testbench.target.signal_name@ (@signal_type@ is meant to be the same as for getting value macro).
h4. Input interface adapter
_Input interface adapter_ is a process defined in reference model adapter and bound with one of the input interfaces. Input interface adapter is called by @CPPTESK_START_STIMULUS(mode)@ macro (see chapter _“Operation”_) or by @CPPTESK_RECV_STIMULUS(mode, interface, message)@ macro (see chapter _“Stimulus receiving”_). Declaration and definition of input interface adapters are done in typical for processes way.
It should be noticed, that just before the serialization, the input interface adapter should capture the interface. Capturing is made by macro @CPPTESK_CAPTURE_IFACE()@. Correspondingly, after the serialization, the interface should be released by macro @CPPTESK_RELEASE_IFACE()@.
Example:
<pre><code class="cpp">
#include <hw/media.hpp>
CPPTESK_ADAPTER(MyAdapter, MyModel) {
CPPTESK_DECLARE_PROCESS(serialize_input);
...
};
CPPTESK_DEFINE_PROCESS(MyAdapter::serialize_input) {
MyMessage msg = CPPTESK_CAST_MESSAGE(MyMessage);
// start serialization process
CPPTESK_START_PROCESS();
// capture input interface
CPPTESK_CAPTURE_IFACE();
// set operation start strobe
inputs.start = 1;
// set information signals
inputs.addr = msg.get_addr();
inputs.data = msg.get_data();
// one cycle delay
CPPTESK_CYCLE();
// reset of operation strobe
inputs.start = 0;
// release input interface
CPPTESK_RELEASE_IFACE();
// stop serialization process
CPPTESK_STOP_PROCESS();
}
</code></pre>
Binding of adapter and interface is made in reference model constructor by means of macro @CPPTESK_SET_INPUT_ADAPTER(interface_name, adapter_full_name)@.
Example:
<pre><code class="cpp">
MyAdapter::MyAdapter{
CPPTESK_SET_INPUT_ADAPTER(input_iface, MyAdater::serialize_input);
...
};
</code></pre>
*Notice*: when input interface adapter being registered, its full name (including the name of reference model adapter class) should be used.
h4. Output interface adapter
Output interface adapter is a process defined in reference model adapter and bound with one of the output interfaces, Output interface adapter is called by @CPPTESK_SEND_REACTION(mode, interface, message)@ macro (see chapter _“Reaction sending”_). Declaration and definition of output interface adapters are done by means of the following macros.
* @CPPTESK_WAIT_REACTION(condition)@ - wait for reaction and allow reaction arbiter to access the reaction;
* @CPPTESK_NEXT_REACTION()@ - releasing of reaction arbiter (see chapter _“Reaction arbiter”_).
Example:
<pre><code class="cpp">
#include <hw/media.hpp>
CPPTESK_ADAPTER(MyAdapter, MyModel) {
CPPTESK_DECLARE_PROCESS(deserialize_output);
...
};
CPPTESK_DEFINE_PROCESS(MyAdapter::deserialize_input) {
// get reference to the message object
MyMessage &msg = CPPTESK_CAST_MESSAGE(MyMessage);
// start deserialization process
CPPTESK_START_PROCESS();
// wait for result strobe
CPPTESK_WAIT_REACTION(outputs.result);
// read data
msg.set_data(outputs.data);
// release reaction arbiter
CPPTESK_NEXT_REACTION();
// stop deserialization process
CPPTESK_STOP_PROCESS();
}
</code></pre>
The waiting for the implementation reaction time is restricted by a timeout. The timeout is set by macro @CPPTESK_SET_REACTION_TIMEOUT(timeout)@, which as well as macro @CPPTESK_SET_OUTPUT_ADAPTER(interface_name, adapter_full_name)@ is called in constructor of reference model adapter.
Example:
<pre><code class="cpp">
MyAdapter::MyAdapter{
CPPTESK_SET_OUTPUT_ADAPTER(output_iface, MyAdater::deserialize_output);
CPPTESK_SET_REACTION_TIMEOUT(100);
...
};
</code></pre>
*Notice*: when output interface adapter being registered, its full name (including the name of reference model adapter class) should be used.
h4. Output interface listener (deprecated feature)
_Output interface listener_ is a special-purpose process, waiting for appearing of implementation reactions at the beginning of each cycle, and registering error in case of unexpected reactions. Definition of listeners is made by @CPPTESK_DEFINE_BASIC_OUTPUT_LISTENER(name, interface_name, condition)@ macro.
Example:
<pre><code class="cpp">
#include <hw/media.hpp>
CPPTESK_ADAPTER(MyAdapter, MyModel) {
CPPTESK_DEFINE_BASIC_OUTPUT_LISTENER(output_listener,
output_iface, outputs.result);
...
};
</code></pre>
Output interface listener is started in constructor of reference model adapter by macro @CPPTESK_CALL_OUTPUT_LISTENER(listener_full_name, interface_name)@.
Example:
<pre><code class="cpp">
MyAdapter::MyAdapter{
...
CPPTESK_CALL_OUTPUT_LISTENER(MyAdapter::output_listener, output_iface);
...
};
</code></pre>
h4. Reaction arbiter
_Reaction arbiter_ (_output interface arbiter_) is aimed for matching implementation reactions (received from HDL-model) with specification reactions (calculated by reference model). Having been matched, the reaction pairs are sent to comparator, showing an error if there is difference in data between two reactions (see chapter _“Comparator of output messages”_).
The common types of arbiters are the following.
* @CPPTESK_FIFO_ARBITER@ — implementation reaction having been received, the arbiter prefers specification reaction which was created by the earliest among the other reactions call of macro @CPPTESK_SEND_REACTION()@ (see chapter _“Reaction sending”_).
* @CPPTESK_PRIORITY_ARBITER@ — the arbiter prefers specification reaction which was created with the highest priority by macro @CPPTESK_SEND_REACTION()@ (see chapter _“Process priority”_).
To declare reaction arbiter in reference model adapter class is possible by means of macro @CPPTESK_DECLARE_ARBITER(type, name)@. To bind arbiter with output interface is possible by means of macro @CPPTESK_SET_ARBITER(interface, arbiter)@, which should be called in constructor of reference model adapter.
Example:
<pre><code class="cpp">
#include <hw/media.hpp>
CPPTESK_ADAPTER(MyAdapter, MyModel) {
CPPTESK_DECLARE_ARBITER(CPPTESK_FIFO_ARBITER, output_iface_arbiter);
...
};
MyAdapter::MyAdapter() {
CPPTESK_SET_ARBITER(output_iface, output_iface_arbiter);
...
}
</code></pre>
h2. Test coverage description
_Test coverage_ is aimed for evaluation of _test completeness_. As a rule, test coverage structure is described explicitly by enumerating of all possible in the test situations (test situations). To describe complex test situations, composition of simpler test coverage structures is used.
Test coverage can be described in the main class of reference model or moved to external class (test coverage class). In the second case, the class with test coverage description should have a reference to the reference model (see chapter _“Test coverage class”_).
h3. Class of test coverage
Class of test coverage is a class containing definition of test coverage structure and functions calculating test situations. As test coverage is defined in terms of reference model, test coverage class should have a reference to the main class of reference model. To trace test situations, test coverage class has test situation tracer — an object of @CoverageTracker@ class (@namespace cpptesk::tracer::coverage@) and function tracing test situations.
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
#include <tracer/tracer.hpp>
class MyModel;
// Declaration of test coverage class
class MyCoverage {
public:
MyCoverage(MyModel &model): model(model) {}
// Test situation tracer
CoverageTracker tracker;
// Description of test coverage structure
CPPTESK_DEFINE_ENUMERATED_COVERAGE(MY_COVERAGE, "My coverage", (
(SITUATION_1, "Situation 1"),
...
(SITUATION_N, "Situation N")
));
// Function calculating test situation: signature of the function
// contains all necessary for it parameters
MY_COVERAGE cov_MY_COVERAGE(...) const;
// Function tracing test situations: signature of the function
// is the same as signature of the previous function
void trace_MY_COVERAGE(...);
...
private:
// Reference to the reference model
MyModel &model;
};
</code></pre>
h3. Test coverage structure
Test coverage structure is described by means of _enumerated coverage_, _coverage compositions_, _excluded coverage composition_, and _test coverage aliases_.
h4. Enumerated coverage
_Enumerated coverage_, as it goes from the coverage name, is defined by explicit enumeration of all possible test situations by macro @CPPTESK_DEFINE_ENUMERATED_COVERAGE(coverage, description, situations)@, where coverage is an identifier of the coverage type, description is a string, and situations is the list of situations like @((id, description), ...)@.
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
CPPTESK_DEFINE_ENUMERATED_COVERAGE(FIFO_FULLNESS, "FIFO fullness", (
(FIFO_EMPTY, "Empty"),
...
(FIFO_FULL, "Full")
));
</code></pre>
h4. Coverage composition
_Coverage composition_ allows creation of test situation structure basing on two test coverage structures, containing Cartesian product of situations from both initial structures. Coverage composition is made by means of macro @CPPTESK_DEFINE_COMPOSED_COVERAGE(type, description, coverage_1, coverage_2)@. Description of new test situations is made according to the pattern @"%s,%s"@.
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
CPPTESK_DEFINE_ENUMERATED_COVERAGE(COVERAGE_A, "Coverage A", (
(A1, "A one"),
(A2, "A two")
));
CPPTESK_DEFINE_ENUMERATED_COVERAGE(COVERAGE_B, "Coverage B", (
(B1, "B one"),
(B2, "B two")
));
// Product of structures A and B makes the following situations:
// (COVERAGE_AxB::Id(A1, B1), "A one, B one")
// (COVERAGE_AxB::Id(A1, B2), "A one, B two")
// (COVERAGE_AxB::Id(A2, B1), "A two, B one")
// (COVERAGE_AxB::Id(A2, B2), "A two, B two")
CPPTESK_DEFINE_COMPOSED_COVERAGE(COVERAGE_AxB, "Coverage AxB",
COVERAGE_A, COVERAGE_B);
</code></pre>
h4. Excluded coverage composition
To make product of test coverage structures and exclude unreachable test situations is possible by macro @CPPTESK_DEFINE_COMPOSED_COVERAGE_EXCLUDING(type, description, coverage_1, coverage_2, excluded)@, where excluded is the list like @({coverage_1::id, coverage_2::id}, ... )@. Instead of test situation identifier, macro @ANY()@ can be used. To product coverage structures being products themselves, correspondent tuples should be used instead of pairs.
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
CPPTESK_DEFINE_ENUMERATED_COVERAGE(COVERAGE_A, "Coverage A", (
(A1, "A one"),
(A2, "A two")
));
CPPTESK_DEFINE_ENUMERATED_COVERAGE(COVERAGE_B, "Coverage B", (
(B1, "B one"),
(B2, "B two")
));
// The following composition makes the following test situations:
// (COVERAGE_AxB::Id(A1, B2), "A one, B two")
// (COVERAGE_AxB::Id(A2, B1), "A two, B one")
// (COVERAGE_AxB::Id(A2, B2), "A two, B two")
CPPTESK_DEFINE_COMPOSED_COVERAGE_EXCLUDING(COVERAGE_AxB, "Coverage AxB",
COVERAGE_A, COVERAGE_B, ({COVERAGE_A::A1, COVERAGE_B::B1}));
</code></pre>
h4. Test coverage alias
To make a test coverage alias (test coverage with different name, but with the same test situations), macro @CPPTESK_DEFINE_ALIAS_COVERAGE(alias, description, coverage)@ should be used.
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
CPPTESK_DEFINE_ENUMERATED_COVERAGE(COVERAGE_A, "Coverage A", (
(A1, "A one"),
(A2, "A two")
));
// COVERAGE_B – alias of COVERAGE_A
CPPTESK_DEFINE_ALIAS_COVERAGE(COVERAGE_B, "Coverage B", COVERAGE_A);
</code></pre>
h3. Calculating current test situation function
_Calculating current test situation function_ is a function, which returns identifier of the current test situation (see chapter _“Structure of the test coverage”_), having analyzed the reference model state and (possibly) input parameters of the operation. Identifier of test situation for enumerated coverage looks like @coverage::identifier@ and @class::coverage::identifier@ when used outside of test coverage class. Calculating current test situation function for production of coverage structures can be obtained by calling functions for particular coverage structures and “production” of their results (operator @*@ should be appropriately overloaded).
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
class MyCoverage {
// definition of the enumerated coverage structure COVERAGE_A
CPPTESK_DEFINE_ENUMERATED_COVERAGE(COVERAGE_A, "Coverage A", (
(A1, "A one"),
(A2, "A two")
));
// test situation calculating function for coverage COVERAGE_A
COVERAGE_A cov_COVERAGE_A(int a) const {
switch(a) {
case 1: return COVERAGE_A::A1;
case 2: return COVERAGE_A::A2;
}
assert(false);
}
// definition of COVERAGE_B – alias of COVERAGE_A
CPPTESK_DEFINE_ALIAS_COVERAGE(COVERAGE_B, "Coverage B", COVERAGE_A);
// test situation calculating function for coverage COVERAGE_B
COVERAGE_B cov_COVERAGE_B(int b) const {
return cov_COVERAGE_A(b);
}
// definition of COVERAGE_AxB – production of COVERAGE_A and COVERAGE_B
CPPTESK_DEFINE_COMPOSED_COVERAGE(COVERAGE_AxB, "Coverage AxB",
COVERAGE_A, COVERAGE_B);s
// test situation calculating function of coverage COVERAGE_AxB
COVERAGE_AxB cov_COVERAGE_AxB(int a, int b) const {
return cov_COVERAGE_A(a) * cov_COVERAGE_B(b);
}
...
};
</code></pre>
h3. Tracing test situation function
_Tracing test situation function_ is defined for each upper-level test coverage structure. As tracing function calls test situation calculating function, their parameters usually coincide. Implementation of this function is based on test situation tracer, being an object of class @CoverageTracker@ (@namespace cpptesk::tracer::coverage@).
Example:
<pre><code class="cpp">
#include <ts/coverage.hpp>
#include <tracer/tracer.hpp>
CoverageTracker tracer;
void trace_COVERAGE_A(int a) {
tracer << cov_COVERAGE_A(a);
}
</code></pre>
h2. Development of test scenario
_Test scenario_ is a high-level specification of test, which being interpreted by test engine (see chapter _“Test scenario running”_) is used by test system for test sequence generation. Test scenario is developed as a special class named scenario class.
h3. Class of scenario
Scenario class is declared by macro @CPPTESK_SCENARIO(name)@.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
CPPTESK_SCENARIO(MyScenario) {
...
private:
// testing is done via reference model adapter
MyAdapter dut;
};
</code></pre>
_Test scenario initialization_ and _finalization methods_, _scenario methods_, and _current state function_ are declared in scenario class.
h4. Test scenario initialization method
_Test scenario initialization method_ includes actions which should have been made right before test start. It is defined by overloading of base class virtual method @bool init(int argc, char **argv)@. It returns true in case of successful initialization and false in case of some problem.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
CPPTESK_SCENARIO(MyScenario) {
public:
virtual bool init(int argc, char **argv) {
dut.initialize();
std::cout << "Test has started..." << std::endl;
}
...
};
</code></pre>
h4. Test scenario finalizing method
_Test scenario finalizing method_ contains actions which should be done right after test finish. It is defined by overloading of base class virtual method @void finish()@.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
CPPTESK_SCENARIO(MyScenario) {
public:
virtual void finish() {
dut.finalize();
std::cout << "Test has finished..." << std::endl;
}
...
};
</code></pre>
h4. Scenario method
_Scenario methods_ iterate parameters of input messages and run operations by means of reference model adapter. One scenario class may contain several scenario method declarations. Scenario method returns value of bool type, which is interpreted as a flag of some problem. The only parameter of scenario method is an iteration context, which is an object containing variables to be iterated by scenario method (iteration variables). Definition of scenario method starts from calling macro @CPPTESK_ITERATION_BEGIN@, and finishes with @CPPTESK_ITERATION_END@.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
CPPTESK_SCENARIO(MyScenario) {
public:
bool scenario(cpptesk::ts::IntCtx &ctx);
...
};
bool MyScenario::scenario(cpptesk::ts::IntCtx &ctx) {
CPPTESK_ITERATION_BEGIN
...
CPPTESK_ITERATION_END
}
</code></pre>
Scenario methods are registered by macro @CPPTESK_ADD_SCENARIO_METHOD(full_name)@ in scenario class constructor.
Example:
<pre><code class="cpp">
MyScenario::MyScenario() {
CPPTESK_ADD_SCENARIO_METHOD(MyScenario::scenario);
...
}
</code></pre>
h4. Access to iteration variables
_Iteration variables_ are fields of _iteration context_, which is a parameter of scenario method. To access iteration variables is possible by macro @CPPTESK_ITERATION_VARIABLE(name)@, where name is a name of one of the iteration context fields.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
bool MyScenario::scenario(cpptesk::ts::IntCtx &ctx) {
// get reference to iteration variable
int &i = CPPTESK_ITERATION_VARIABLE(i);
CPPTESK_ITERATION_BEGIN
for(i = 0; i < 10; i++) {
...
}
CPPTESK_ITERATION_END
}
</code></pre>
h4. Test action block
_Test action_ (preparation of input message and start of operation) is made in a code block @CPPTESK_ITERATION_ACTION{...}@ located in scenario method.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
...
CPPTESK_ITERATION_BEGIN
for(i = 0; i < 10; i++) {
...
// test action block
CPPTESK_ITERATION_ACTION {
// input message randomization
CPPTESK_RANDOMIZE_MESSAGE(input_msg);
input_msg.set_addr(i);
// start operation
CPPTESK_CALL_STIMULUS_OF(dut, MyModel::operation,
dut.input_iface, input_msg);
...
}
}
CPPTESK_ITERATION_END
</code></pre>
h4. Scenario action finishing
Each iteration of scenario method is finished by @CPPTESK_ITERATION_YIELD(verdict)@ macro, quitting from scenario method. When being called next time, scenario method will continue its execution from next iteration.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
...
CPPTESK_ITERATION_BEGIN
for(i = 0; i < 10; i++) {
...
// test action block
CPPTESK_ITERATION_ACTION {
...
// quit from scenario method and return verdict
CPPTESK_ITERATION_YIELD(dut.verdict());
}
}
CPPTESK_ITERATION_END
</code></pre>
h4. Delays
Making _delays_ (sending of stimuli at different time of HDL-model simulation) in tests requires development of at least one method with calling reference model method @cycle()@. In case of possibility of parallel stimulus running, the most convenient way of usage method @cycle()@ is to call this method from purposely created scenario method @nop()@ (name of this method is unrestricted). Notice that in this case method @cycle()@ should not be called from any other method.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
bool MyScenario::nop(cpptesk::ts::IntCtx& ctx) {
CPPTESK_ITERATION_BEGIN
CPPTESK_ITERATION_ACTION {
dut.cycle();
CPPTESK_ITERATION_YIELD(dut.verdict());
}
CPPTESK_ITERATION_END
}
</code></pre>
*Notice*: scenario method @nop()@ should be registered before any other scenario methods.
h3. Calculating current state function
_Calculating current state function_ is needed for test engines, using exploration of target system state graph for creation of test sequences. Returning by function value is interpreted as system state. Type of the returning value and function name are unrestricted. Method does not allow parameters.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
CPPTESK_SCENARIO(MyScenario) {
public:
...
int get_model_state() {
return dut.buffer.size();
}
};
</code></pre>
Setting up of calculating current state function is made by method @void setup(...)@. in test scenario constructor.
Example:
<pre><code class="cpp">
#include <ts/scenario.hpp>
MyScenario::MyScenario() {
setup("My scenario",
UseVirtual::init,
UseVirtual::finish,
&MyScenario::get_model_state);
...
}
</code></pre>
h3. Test scenario running
Test scenario running at local computer is made by calling function @localmain(engine, scenario.getTestScenario(), argc, argv)@ (namespace @cpptesk::ts@).
Available test engines are the following (namespace @cpptesk::ts::engine@).
* @fsm@ — generator of test sequence based on state graph exploration;
* @rnd@ — generator of randomized test sequence.
Example:
<pre><code class="cpp">
#include <netfsm/engines.hpp>
using namespace cpptesk::ts;
using namespace cpptesk::ts::engine;
...
MyScenario scenario;
localmain(fsm, scenario.getTestScenario(), argc, argv);
</code></pre>
h2. Auxiliary possibilities
C++TESK toolkit includes the following auxiliary possibilities: assertions and debug print. These possibilities can be used in reference models and in all test system components (adapters, test scenarios, etc). Their main aim is to facilitate debug of test system.
h3. Assertions
_Assertions_ are predicates (logic constructions) used for description of program properties and, as a rule, checked during runtime. If assertion is violated (predicate shows false), error is fixed and program is stopped. To make assertions is possible by @CPPTESK_ASSERTION(predicate, description)@ macro, where predicate is a checking property, and description is a string describing error bound with violation of this property.
Example:
<pre><code class="cpp">
#include <hw/assertion.hpp>
...
CPPTESK_ASSERTION(pointer, "pointer is null");
</code></pre>
h3. Debug print
_Debug print_ is devoted to debug of test system. In contrast to typical printing by means of, e.g., STL streams, adjustment of debug print is easier (turning on/off, changing of printing color, etc).
h4. Debug print macros
Debug print is commonly made by macro @CPPTESK_DEBUG_PRINT(level, message)@, where level is a level of debug print (see chapter _“Debug print levels”_) and message is a printing debug message, and macro @CPPTESK_DEBUG_PRINTF(level, formal, parameters)@, where @(format, parameters)@ is a formatted string and values of used in the string parameters in the same format as they are used by C library function @printf()@.
Example:
<pre><code class="cpp">
#include <hw/debug.hpp>
using namespace cpptesk::hw;
...
CPPTESK_DEBUG_PRINT(DEBUG_USER, "The input message is "
<< CPPTESK_GET_MESSAGE());
...
CPPTESK_DEBUG_PRINTF(DEBUG_USER, "counter=%d", counter);
</code></pre>
*Notice*: as a debug message in macro @CPPTESK_DEBUG_PRINT()@ any “stream expression” (allowed for usage in standard C++ STL output streams expressions) can be used.
To add location information of debug macro to debug message (file name and string number) is possible by means of macros @CPPTESK_DEBUG_PRINT_FILE_LINE()@ and @CPPTESK_DEBUG_PRINTF_FILE_LINE()@. Their parameters are the same as of macros mentioned above.
h3. Process call stack printing
To print process call stack of reference model is possible by macro @CPPTESK_CALL_STACK()@, which can be used inside and instead of debug message of macro @CPPTESK_DEBUG_PRINT()@.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
CPPTESK_DEFINE_PROCESS(MyModel::some_process) {
CPPTESK_START_PROCESS();
CPPTESK_DEBUG_PRINT(DEBUG_USER, "Call stack is "
<< CPPTESK_CALL_STACK());
...
CPPTESK_STOP_PROCESS();
}
</code></pre>
*Notice*: macro @CPPTESK_CALL_STACK()@ can be used only inside on reference model.
h3. Colored debug print
To facilitate manual search of debug messages of a certain type among all debug print is possible by means of colored debug print macros @CPPTESK_COLORED_DEBUG_PRINT(level, color, background_color, message)@, @CPPTESK_COLORED_DEBUG_PRINTF(level, color, background_color, format, parameters)@, and also macros @CPPTESK_COLORED_DEBUG_PRINT_FILE_LINE()@ and @CPPTESK_COLORED_DEBUG_PRINTF_FILE_LINE()@.
The following color constants are defined (namespace @cpptesk::hw@):
* @BLACK@ — black;
* @RED@ — red;
* @GREEN@ — green;
* @YELLOW@ — yellow;
* @BLUE@ — blue;
* @MAGENTA@ — purple;
* @CYAN@ — cyan;
* @WHITE@ — white.
Example:
<pre><code class="cpp">
#include <hw/debug.hpp>
using namespace cpptesk::hw;
...
CPPTESK_COLORED_DEBUG_PRINT_FILE_LINE(DEBUG_USER, RED, BLACK,
"The input message is " << CPPTESK_GET_MESSAGE());
...
CPPTESK_COLORED_DEBUG_PRINTF(DEBUG_USER, WHITE, BLACK,
"counter=%d", counter);
</code></pre>
h3. Controlling indents in debug print
To control indents in debug print is possible by @CPPTESK_SET_DEBUG_INDENT(indent)@, @CPPTESK_BEGIN_DEBUG_INDENT@, and @CPPTESK_END_DEBUG_INDENT@ macros. Macro @CPPTESK_SET_DEBUG_INDENT@ sets indent value (not negative integer) returning its old value. Macros @CPPTESK_BEGIN_DEBUG_INDENT@ and @CPPTESK_END_DEBUG_INDENT@ are used in complementary way: the first one increases indent, the second one decreases indent by one point.
Example:
<pre><code class="cpp">
#include <hw/debug.hpp>
using namespace cpptesk::hw;
...
unsigned old_indent = CPPTESK_SET_DEBUG_INDENT(2);
...
CPPTESK_BEGIN_DEBUG_INDENT
{
CPPTESK_DEBUG_PRINT(DEBUG_USER, "Some message");
...
}
CPPTESK_END_DEBUG_INDENT
</code></pre>
h3. Debug print levels
There is a level of debug message parameter among other debug print parameters. Level characterizes importance of the message. Usually, debug messages of different levels are colored differently. The following debug levels are defined (namespace @cpptesk::hw@):
* @DEBUG_MORE@ — detailed debug messages produced by toolkit itself;
* @DEBUG_INFO@ — basic debug messages produced by toolkit itself;
* @DEBUG_USER@ — user’s debug messages;
* @DEBUG_WARN@ — warnings (typically, produced by toolkit itself);
* @DEBUG_FAIL@ — messages about failures (typically, produced by toolkit itself).
The most “important” level is @DEBUG_FAIL@, then @DEBUG_WARN@, etc. @DEBUG_USER@ is the only one level for user’s messages.
h3. Debug print setting up
To set up the volume of debug print messages is possible by selection of debug print level, and only those messages will be printed, which has debug level being not less than selected one. It is done by macro @CPPTESK_SET_DEBUG_LEVEL(debug_level, colored)@. This macro has an additional Boolean parameter colored, turning on/off coloring. Debug level @DEBUG_INFO@ is set by default. Special level @DEBUG_NONE@ can be used to switch off debug print totally.
Each debug print level can be assigned with colors for messages of this level. It is done by macro @CPPTESK_SET_DEBUG_STYLE(level, tag_color, tag_background_color, color, background_color)@.
Example:
<pre><code class="cpp">
#include <hw/model.hpp>
using namespace cpptesk::hw;
...
// reference model constructor
MyModel::MyModel() {
// print messages with failures only,
// switch on message coloring
CPPTESK_SET_DEBUG_LEVEL(DEBUG_FAIL, true);
// [FAIL] Error message style.
CPPTESK_SET_DEBUG_STYLE(DEBUG_FAIL, BLACK, RED, RED, BLACK);
}
</code></pre>