The Symbolic value. Either a constant (Left) or a symbolic value (Right Cached). Note that caching is essential for making sure sharing is preserved.

A class for capturing values that have a sign and a size (finite or infinite) minimal complete definition: kindOf. This class can be automatically derived for data-types that have a Data instance; this is useful for creating uninterpreted sorts.

Kind of symbolic value

CW represents a concrete word of a fixed size: Endianness is mostly irrelevant (see the FromBits class). For signed words, the most significant digit is considered to be the sign.

A constant value

Convert a CW to a Haskell boolean (NB. Assumes input is well-kinded)

Arrays implemented in terms of SMT-arrays: http://smtlib.cs.uiowa.edu/theories-ArraysEx.shtml

• Maps directly to SMT-lib arrays
• Reading from an unintialized value is OK and yields an unspecified result
• Can check for equality of these arrays
• Cannot quick-check theorems using SArr values
• Typically slower as it heavily relies on SMT-solving for the array theory

Read the array element at a

Reset all the elements of the array to the value b

Update the element at a to be b

Merge two given arrays on the symbolic condition Intuitively: mergeArrays cond a b = if cond then a else b. Merging pushes the if-then-else choice down on to elements

Create a named new array, with an optional initial value

Compare two arrays for equality

A Symbolic computation. Represented by a reader monad carrying the state of the computation, layered on top of IO for creating unique references to hold onto intermediate results.

Quantifiers: forall or exists. Note that we allow arbitrary nestings.

Create a symbolic value, based on the quantifier we have. If an explicit quantifier is given, we just use that. If not, then we pick existential for SAT calls and universal for everything else. randomCW is used for generating random values for this variable when used for quickCheck purposes.

Boolean True.

Boolean False.

Convert from a Boolean.

Extract a bool, by properly interpreting the integer stored.

Convert from an Integer.

Extract an integer from a concrete value.

Convert from a Float

Convert from a Float

Convert from a Rational

Grab the numerator of an SReal, if available

Grab the denominator of an SReal, if available

Equality.

Inequality.

Constructing [x, y, .. z] and [x .. y]. Only works when all arguments are concrete and integral and the result is guaranteed finite Note that the it isn't "obviously" clear why the following works; after all we're doing the construction over Integer's and mapping it back to other types such as SIntN/SWordN. The reason is that the values we receive are guaranteed to be in their domains; and thus the lifting to Integers preserves the bounds; and then going back is just fine. So, things like [1, 5 .. 200] :: [SInt8] work just fine (end evaluate to empty list), since we see [1, 5 .. -56] in the Integer domain. Also note the explicit check for s /= f below to make sure we don't stutter and produce an infinite list.

Less than.

Greater than.

Less than or equal to.

Greater than or equal to.

Addition.

Multiplication.

Subtraction.

Unary minus.

Absolute value.

Division.

Quotient: Overloaded operation whose meaning depends on the kind at which it is used: For unbounded integers, it corresponds to the SMT-Lib "div" operator (Euclidean division, which always has a non-negative remainder). For unsigned bitvectors, it is "bvudiv"; and for signed bitvectors it is "bvsdiv", which rounds toward zero. All operations have unspecified semantics in case y = 0.

Remainder: Overloaded operation whose meaning depends on the kind at which it is used: For unbounded integers, it corresponds to the SMT-Lib "mod" operator (always non-negative). For unsigned bitvectors, it is "bvurem"; and for signed bitvectors it is "bvsrem", which rounds toward zero (sign of remainder matches that of x). All operations have unspecified semantics in case y = 0.

Exponentiation.

Add a constant value:

Increment:

Decrement:

Bitwise and.

Bitwise or.

Bitwise xor.

Bitwise complement.

Shift left by a constant amount. Translates to the "bvshl" operation in SMT-Lib.

Shift right by a constant amount. Translates to either "bvlshr" (logical shift right) or "bvashr" (arithmetic shift right) in SMT-Lib, depending on whether x is a signed bitvector.

Rotate-left, by a constant

Rotate-right, by a constant

Extract bit-sequences.

Join two words, by concataneting

Convert a symbolic bitvector from unsigned to signed.

Convert a symbolic bitvector from signed to unsigned.

Total indexing operation. svSelect xs default index is intuitively the same as xs !! index, except it evaluates to default if index overflows. Translates to SMT-Lib tables.

Convert an SVal from kind Bool to an unsigned bitvector of size 1.

Convert an SVal from a bitvector of size 1 (signed or unsigned) to kind Bool.

Test the value of a bit. Note that we do an extract here as opposed to masking and checking against zero, as we found extraction to be much faster with large bit-vectors.

Set a given bit at index

Generalization of svShl, where the shift-amount is symbolic. The first argument should be a bounded quantity.

Generalization of svShr, where the shift-amount is symbolic. The first argument should be a bounded quantity.

NB. If the shiftee is signed, then this is an arithmetic shift; otherwise it's logical.

Generalization of svRol, where the rotation amount is symbolic. The first argument should be a bounded quantity.

Generalization of svRor, where the rotation amount is symbolic. The first argument should be a bounded quantity.

Un-bit-blast from little-endian representation to a word of the right size. The input is assumed to be unsigned.

Un-bit-blast from big-endian representation to a word of the right size. The input is assumed to be unsigned.

Bit-blast: Little-endian. Assumes the input is a bit-vector.

Bit-blast: Big-endian. Assumes the input is a bit-vector.

If-then-else. This one will force branches.

Lazy If-then-else. This one will delay forcing the branches unless it's really necessary.

Merge two symbolic values, at kind k, possibly force'ing the branches to make sure they do not evaluate to the same result.

Reduce a condition (i.e., try to concretize it) under the given path

Uninterpreted constants and functions. An uninterpreted constant is a value that is indexed by its name. The only property the prover assumes about these values are that they are equivalent to themselves; i.e., (for functions) they return the same results when applied to same arguments. We support uninterpreted-functions as a general means of black-box'ing operations that are irrelevant for the purposes of the proof; i.e., when the proofs can be performed without any knowledge about the function itself.

Proves the predicate using the given SMT-solver

Find a satisfying assignment using the given SMT-solver

Find all satisfying assignments using the given SMT-solver

Check safety using the given SMT-solver

Prove a property with multiple solvers, running them in separate threads. The results will be returned in the order produced.

Prove a property with multiple solvers, running them in separate threads. Only the result of the first one to finish will be returned, remaining threads will be killed.

Find a satisfying assignment to a property with multiple solvers, running them in separate threads. The results will be returned in the order produced.

Find a satisfying assignment to a property with multiple solvers, running them in separate threads. Only the result of the first one to finish will be returned, remaining threads will be killed.

Dynamic variant of quick-check

A prove call results in a ThmResult

A sat call results in a SatResult The reason for having a separate SatResult is to have a more meaningful Show instance.

A safe call results in a SafeResult

An allSat call results in a AllSatResult. The boolean says whether we should warn the user about prefix-existentials.

The result of an SMT solver call. Each constructor is tagged with the SMTConfig that created it so that further tools can inspect it and build layers of results, if needed. For ordinary uses of the library, this type should not be needed, instead use the accessor functions on it. (Custom Show instances and model extractors.)

Parse a signed/sized value from a sequence of CWs

Extract a model, the result is a tuple where the first argument (if True) indicates whether the model was "probable". (i.e., if the solver returned unknown.)

Extract a model dictionary. Extract a dictionary mapping the variables to their respective values as returned by the SMT solver. Also see getModelDictionaries.

Solver configuration. See also z3, yices, cvc4, boolector, mathSAT, etc. which are instantiations of this type for those solvers, with reasonable defaults. In particular, custom configuration can be created by varying those values. (Such as z3{verbose=True}.)

Most fields are self explanatory. The notion of precision for printing algebraic reals stems from the fact that such values does not necessarily have finite decimal representations, and hence we have to stop printing at some depth. It is important to emphasize that such values always have infinite precision internally. The issue is merely with how we print such an infinite precision value on the screen. The field printRealPrec controls the printing precision, by specifying the number of digits after the decimal point. The default value is 16, but it can be set to any positive integer.

When printing, SBV will add the suffix ... at the and of a real-value, if the given bound is not sufficient to represent the real-value exactly. Otherwise, the number will be written out in standard decimal notation. Note that SBV will always print the whole value if it is precise (i.e., if it fits in a finite number of digits), regardless of the precision limit. The limit only applies if the representation of the real value is not finite, i.e., if it is not rational.

The printBase field can be used to print numbers in base 2, 10, or 16. If base 2 or 16 is used, then floating-point values will be printed in their internal memory-layout format as well, which can come in handy for bit-precise analysis.

Representation of SMTLib Program versions. As of June 2015, we're dropping support for SMTLib1, and supporting SMTLib2 only. We keep this data-type around in case SMTLib3 comes along and we want to support 2 and 3 simultaneously.

SMT-Lib logics. If left unspecified SBV will pick the logic based on what it determines is needed. However, the user can override this choice using the useLogic parameter to the configuration. This is especially handy if one is experimenting with custom logics that might be supported on new solvers. See http://smtlib.cs.uiowa.edu/logics.shtml for the official list.

Chosen logic for the solver

Optimizer configuration. Note that iterative and quantified approaches are in general not interchangeable. For instance, iterative solutions will loop infinitely when there is no optimal value, but quantified solutions can handle such problems. Of course, quantified problems are harder for SMT solvers, naturally.

Solvers that SBV is aware of

An SMT solver

Default configuration for the Boolector SMT solver

Default configuration for the CVC4 SMT Solver.

Default configuration for the Yices SMT Solver.

Default configuration for the Z3 SMT solver

Default configuration for the MathSAT SMT solver

Default configuration for the ABC synthesis and verification tool.

The default configs corresponding to supported SMT solvers

The currently active solver, obtained by importing Data.SBV. To have other solvers current, import one of the bridge modules Data.SBV.Bridge.ABC, Data.SBV.Bridge.Boolector, Data.SBV.Bridge.CVC4, Data.SBV.Bridge.Yices, or Data.SBV.Bridge.Z3 directly.

The default solver used by SBV. This is currently set to z3.

Check whether the given solver is installed and is ready to go. This call does a simple call to the solver to ensure all is well.

Return the known available solver configs, installed on your machine.

Mark an interim result as an output. Useful when constructing Symbolic programs that return multiple values, or when the result is programmatically computed.

Compiles to SMT-Lib and returns the resulting program as a string. Useful for saving the result to a file for off-line analysis, for instance if you have an SMT solver that's not natively supported out-of-the box by the SBV library. It takes two arguments:

• version: The SMTLib-version to produce. Note that we currently only support SMTLib2.
• isSat : If True, will translate it as a SAT query, i.e., in the positive. If False, will translate as a PROVE query, i.e., it will negate the result. (In this case, the check-sat call to the SMT solver will produce UNSAT if the input is a theorem, as usual.)

Create both SMT-Lib1 and SMT-Lib2 benchmarks. The first argument is the basename of the file, SMT-Lib1 version will be written with suffix ".smt1" and SMT-Lib2 version will be written with suffix ".smt2". The Bool argument controls whether this is a SAT instance, i.e., translate the query directly, or a PROVE instance, i.e., translate the negated query. (See the second boolean argument to compileToSMTLib for details.)

The code-generation monad. Allows for precise layout of input values reference parameters (for returning composite values in languages such as C), and return values.

Sets RTC (run-time-checks) for index-out-of-bounds, shift-with-large value etc. on/off. Default: False.

Sets driver program run time values, useful for generating programs with fixed drivers for testing. Default: None, i.e., use random values.

Should we generate a driver program? Default: True. When a library is generated, it will have a driver if any of the contituent functions has a driver. (See compileToCLib.)

Should we generate a Makefile? Default: True.

Creates an atomic input in the generated code.

Creates an array input in the generated code.

Creates an atomic output in the generated code.

Creates an array output in the generated code.

Creates a returned (unnamed) value in the generated code.

Creates a returned (unnamed) array value in the generated code.

Adds the given lines to the header file generated, useful for generating programs with uninterpreted functions.

Adds the given lines to the program file generated, useful for generating programs with uninterpreted functions.

Adds the given words to the compiler options in the generated Makefile, useful for linking extra stuff in.

Ignore assertions (those generated by sAssert calls) in the generated C code

Sets number of bits to be used for representing the SInteger type in the generated C code. The argument must be one of 8, 16, 32, or 64. Note that this is essentially unsafe as the semantics of unbounded Haskell integers becomes reduced to the corresponding bit size, as typical in most C implementations.

Sets the C type to be used for representing the SReal type in the generated C code. The setting can be one of C's "float", "double", or "long double", types, depending on the precision needed. Note that this is essentially unsafe as the semantics of infinite precision SReal values becomes reduced to the corresponding floating point type in C, and hence it is subject to rounding errors.

Possible mappings for the SReal type when translated to C. Used in conjunction with the function cgSRealType. Note that the particular characteristics of the mapped types depend on the platform and the compiler used for compiling the generated C program. See http://en.wikipedia.org/wiki/C_data_types for details.

Given a symbolic computation, render it as an equivalent collection of files that make up a C program:

• The first argument is the directory name under which the files will be saved. To save files in the current directory pass Just ".". Use Nothing for printing to stdout.
• The second argument is the name of the C function to generate.
• The final argument is the function to be compiled.

Compilation will also generate a Makefile, a header file, and a driver (test) program, etc.

Create code to generate a library archive (.a) from given symbolic functions. Useful when generating code from multiple functions that work together as a library.

• The first argument is the directory name under which the files will be saved. To save files in the current directory pass Just ".". Use Nothing for printing to stdout.
• The second argument is the name of the archive to generate.
• The third argument is the list of functions to include, in the form of function-name/code pairs, similar to the second and third arguments of compileToC, except in a list.