Z3
Data Structures | Functions | Variables
z3py Namespace Reference

Data Structures

class  Context
 
class  Z3PPObject
 ASTs base class. More...
 
class  AstRef
 
class  SortRef
 
class  FuncDeclRef
 Function Declarations. More...
 
class  ExprRef
 Expressions. More...
 
class  BoolSortRef
 Booleans. More...
 
class  BoolRef
 
class  PatternRef
 Patterns. More...
 
class  QuantifierRef
 Quantifiers. More...
 
class  ArithSortRef
 Arithmetic. More...
 
class  ArithRef
 
class  IntNumRef
 
class  RatNumRef
 
class  AlgebraicNumRef
 
class  BitVecSortRef
 Bit-Vectors. More...
 
class  BitVecRef
 
class  BitVecNumRef
 
class  ArraySortRef
 Arrays. More...
 
class  ArrayRef
 
class  Datatype
 
class  ScopedConstructor
 
class  ScopedConstructorList
 
class  DatatypeSortRef
 
class  DatatypeRef
 
class  ParamsRef
 Parameter Sets. More...
 
class  ParamDescrsRef
 
class  Goal
 
class  AstVector
 
class  AstMap
 
class  FuncEntry
 
class  FuncInterp
 
class  ModelRef
 
class  Statistics
 Statistics. More...
 
class  CheckSatResult
 
class  Solver
 
class  Fixedpoint
 Fixedpoint. More...
 
class  FiniteDomainSortRef
 
class  FiniteDomainRef
 
class  FiniteDomainNumRef
 
class  OptimizeObjective
 Optimize. More...
 
class  Optimize
 
class  ApplyResult
 
class  Tactic
 
class  Probe
 
class  ParserContext
 
class  FPSortRef
 
class  FPRMSortRef
 
class  FPRef
 
class  FPRMRef
 
class  FPNumRef
 
class  SeqSortRef
 Strings, Sequences and Regular expressions. More...
 
class  CharSortRef
 
class  SeqRef
 
class  CharRef
 
class  ReSortRef
 
class  ReRef
 
class  OnClause
 
class  PropClosures
 
class  UserPropagateBase
 

Functions

def z3_debug ()
 
def enable_trace (msg)
 
def disable_trace (msg)
 
def get_version_string ()
 
def get_version ()
 
def get_full_version ()
 
def open_log (fname)
 
def append_log (s)
 
def to_symbol (s, ctx=None)
 
def z3_error_handler (c, e)
 
def main_ctx ()
 
def get_ctx (ctx)
 
def set_param (*args, **kws)
 
def reset_params ()
 
def set_option (*args, **kws)
 
def get_param (name)
 
def is_ast (a)
 
def eq (a, b)
 
def is_sort (s)
 
def DeclareSort (name, ctx=None)
 
def is_func_decl (a)
 
def Function (name, *sig)
 
def FreshFunction (*sig)
 
def RecFunction (name, *sig)
 
def RecAddDefinition (f, args, body)
 
def deserialize (st)
 
def is_expr (a)
 
def is_app (a)
 
def is_const (a)
 
def is_var (a)
 
def get_var_index (a)
 
def is_app_of (a, k)
 
def If (a, b, c, ctx=None)
 
def Distinct (*args)
 
def Const (name, sort)
 
def Consts (names, sort)
 
def FreshConst (sort, prefix="c")
 
def Var (idx, s)
 
def RealVar (idx, ctx=None)
 
def RealVarVector (n, ctx=None)
 
def is_bool (a)
 
def is_true (a)
 
def is_false (a)
 
def is_and (a)
 
def is_or (a)
 
def is_implies (a)
 
def is_not (a)
 
def is_eq (a)
 
def is_distinct (a)
 
def BoolSort (ctx=None)
 
def BoolVal (val, ctx=None)
 
def Bool (name, ctx=None)
 
def Bools (names, ctx=None)
 
def BoolVector (prefix, sz, ctx=None)
 
def FreshBool (prefix="b", ctx=None)
 
def Implies (a, b, ctx=None)
 
def Xor (a, b, ctx=None)
 
def Not (a, ctx=None)
 
def mk_not (a)
 
def And (*args)
 
def Or (*args)
 
def is_pattern (a)
 
def MultiPattern (*args)
 
def is_quantifier (a)
 
def ForAll (vs, body, weight=1, qid="", skid="", patterns=[], no_patterns=[])
 
def Exists (vs, body, weight=1, qid="", skid="", patterns=[], no_patterns=[])
 
def Lambda (vs, body)
 
def is_arith_sort (s)
 
def is_arith (a)
 
def is_int (a)
 
def is_real (a)
 
def is_int_value (a)
 
def is_rational_value (a)
 
def is_algebraic_value (a)
 
def is_add (a)
 
def is_mul (a)
 
def is_sub (a)
 
def is_div (a)
 
def is_idiv (a)
 
def is_mod (a)
 
def is_le (a)
 
def is_lt (a)
 
def is_ge (a)
 
def is_gt (a)
 
def is_is_int (a)
 
def is_to_real (a)
 
def is_to_int (a)
 
def IntSort (ctx=None)
 
def RealSort (ctx=None)
 
def IntVal (val, ctx=None)
 
def RealVal (val, ctx=None)
 
def RatVal (a, b, ctx=None)
 
def Q (a, b, ctx=None)
 
def Int (name, ctx=None)
 
def Ints (names, ctx=None)
 
def IntVector (prefix, sz, ctx=None)
 
def FreshInt (prefix="x", ctx=None)
 
def Real (name, ctx=None)
 
def Reals (names, ctx=None)
 
def RealVector (prefix, sz, ctx=None)
 
def FreshReal (prefix="b", ctx=None)
 
def ToReal (a)
 
def ToInt (a)
 
def IsInt (a)
 
def Sqrt (a, ctx=None)
 
def Cbrt (a, ctx=None)
 
def is_bv_sort (s)
 
def is_bv (a)
 
def is_bv_value (a)
 
def BV2Int (a, is_signed=False)
 
def Int2BV (a, num_bits)
 
def BitVecSort (sz, ctx=None)
 
def BitVecVal (val, bv, ctx=None)
 
def BitVec (name, bv, ctx=None)
 
def BitVecs (names, bv, ctx=None)
 
def Concat (*args)
 
def Extract (high, low, a)
 
def ULE (a, b)
 
def ULT (a, b)
 
def UGE (a, b)
 
def UGT (a, b)
 
def UDiv (a, b)
 
def URem (a, b)
 
def SRem (a, b)
 
def LShR (a, b)
 
def RotateLeft (a, b)
 
def RotateRight (a, b)
 
def SignExt (n, a)
 
def ZeroExt (n, a)
 
def RepeatBitVec (n, a)
 
def BVRedAnd (a)
 
def BVRedOr (a)
 
def BVAddNoOverflow (a, b, signed)
 
def BVAddNoUnderflow (a, b)
 
def BVSubNoOverflow (a, b)
 
def BVSubNoUnderflow (a, b, signed)
 
def BVSDivNoOverflow (a, b)
 
def BVSNegNoOverflow (a)
 
def BVMulNoOverflow (a, b, signed)
 
def BVMulNoUnderflow (a, b)
 
def is_array_sort (a)
 
def is_array (a)
 
def is_const_array (a)
 
def is_K (a)
 
def is_map (a)
 
def is_default (a)
 
def get_map_func (a)
 
def ArraySort (*sig)
 
def Array (name, *sorts)
 
def Update (a, *args)
 
def Default (a)
 
def Store (a, *args)
 
def Select (a, *args)
 
def Map (f, *args)
 
def K (dom, v)
 
def Ext (a, b)
 
def SetHasSize (a, k)
 
def is_select (a)
 
def is_store (a)
 
def SetSort (s)
 Sets. More...
 
def EmptySet (s)
 
def FullSet (s)
 
def SetUnion (*args)
 
def SetIntersect (*args)
 
def SetAdd (s, e)
 
def SetDel (s, e)
 
def SetComplement (s)
 
def SetDifference (a, b)
 
def IsMember (e, s)
 
def IsSubset (a, b)
 
def CreateDatatypes (*ds)
 
def DatatypeSort (name, ctx=None)
 
def TupleSort (name, sorts, ctx=None)
 
def DisjointSum (name, sorts, ctx=None)
 
def EnumSort (name, values, ctx=None)
 
def args2params (arguments, keywords, ctx=None)
 
def Model (ctx=None)
 
def is_as_array (n)
 
def get_as_array_func (n)
 
def SolverFor (logic, ctx=None, logFile=None)
 
def SimpleSolver (ctx=None, logFile=None)
 
def FiniteDomainSort (name, sz, ctx=None)
 
def is_finite_domain_sort (s)
 
def is_finite_domain (a)
 
def FiniteDomainVal (val, sort, ctx=None)
 
def is_finite_domain_value (a)
 
def AndThen (*ts, **ks)
 
def Then (*ts, **ks)
 
def OrElse (*ts, **ks)
 
def ParOr (*ts, **ks)
 
def ParThen (t1, t2, ctx=None)
 
def ParAndThen (t1, t2, ctx=None)
 
def With (t, *args, **keys)
 
def WithParams (t, p)
 
def Repeat (t, max=4294967295, ctx=None)
 
def TryFor (t, ms, ctx=None)
 
def tactics (ctx=None)
 
def tactic_description (name, ctx=None)
 
def describe_tactics ()
 
def is_probe (p)
 
def probes (ctx=None)
 
def probe_description (name, ctx=None)
 
def describe_probes ()
 
def FailIf (p, ctx=None)
 
def When (p, t, ctx=None)
 
def Cond (p, t1, t2, ctx=None)
 
def simplify (a, *arguments, **keywords)
 Utils. More...
 
def help_simplify ()
 
def simplify_param_descrs ()
 
def substitute (t, *m)
 
def substitute_vars (t, *m)
 
def substitute_funs (t, *m)
 
def Sum (*args)
 
def Product (*args)
 
def Abs (arg)
 
def AtMost (*args)
 
def AtLeast (*args)
 
def PbLe (args, k)
 
def PbGe (args, k)
 
def PbEq (args, k, ctx=None)
 
def solve (*args, **keywords)
 
def solve_using (s, *args, **keywords)
 
def prove (claim, show=False, **keywords)
 
def parse_smt2_string (s, sorts={}, decls={}, ctx=None)
 
def parse_smt2_file (f, sorts={}, decls={}, ctx=None)
 
def get_default_rounding_mode (ctx=None)
 
def set_default_rounding_mode (rm, ctx=None)
 
def get_default_fp_sort (ctx=None)
 
def set_default_fp_sort (ebits, sbits, ctx=None)
 
def Float16 (ctx=None)
 
def FloatHalf (ctx=None)
 
def Float32 (ctx=None)
 
def FloatSingle (ctx=None)
 
def Float64 (ctx=None)
 
def FloatDouble (ctx=None)
 
def Float128 (ctx=None)
 
def FloatQuadruple (ctx=None)
 
def is_fp_sort (s)
 
def is_fprm_sort (s)
 
def RoundNearestTiesToEven (ctx=None)
 
def RNE (ctx=None)
 
def RoundNearestTiesToAway (ctx=None)
 
def RNA (ctx=None)
 
def RoundTowardPositive (ctx=None)
 
def RTP (ctx=None)
 
def RoundTowardNegative (ctx=None)
 
def RTN (ctx=None)
 
def RoundTowardZero (ctx=None)
 
def RTZ (ctx=None)
 
def is_fprm (a)
 
def is_fprm_value (a)
 
def is_fp (a)
 
def is_fp_value (a)
 
def FPSort (ebits, sbits, ctx=None)
 
def fpNaN (s)
 
def fpPlusInfinity (s)
 
def fpMinusInfinity (s)
 
def fpInfinity (s, negative)
 
def fpPlusZero (s)
 
def fpMinusZero (s)
 
def fpZero (s, negative)
 
def FPVal (sig, exp=None, fps=None, ctx=None)
 
def FP (name, fpsort, ctx=None)
 
def FPs (names, fpsort, ctx=None)
 
def fpAbs (a, ctx=None)
 
def fpNeg (a, ctx=None)
 
def fpAdd (rm, a, b, ctx=None)
 
def fpSub (rm, a, b, ctx=None)
 
def fpMul (rm, a, b, ctx=None)
 
def fpDiv (rm, a, b, ctx=None)
 
def fpRem (a, b, ctx=None)
 
def fpMin (a, b, ctx=None)
 
def fpMax (a, b, ctx=None)
 
def fpFMA (rm, a, b, c, ctx=None)
 
def fpSqrt (rm, a, ctx=None)
 
def fpRoundToIntegral (rm, a, ctx=None)
 
def fpIsNaN (a, ctx=None)
 
def fpIsInf (a, ctx=None)
 
def fpIsZero (a, ctx=None)
 
def fpIsNormal (a, ctx=None)
 
def fpIsSubnormal (a, ctx=None)
 
def fpIsNegative (a, ctx=None)
 
def fpIsPositive (a, ctx=None)
 
def fpLT (a, b, ctx=None)
 
def fpLEQ (a, b, ctx=None)
 
def fpGT (a, b, ctx=None)
 
def fpGEQ (a, b, ctx=None)
 
def fpEQ (a, b, ctx=None)
 
def fpNEQ (a, b, ctx=None)
 
def fpFP (sgn, exp, sig, ctx=None)
 
def fpToFP (a1, a2=None, a3=None, ctx=None)
 
def fpBVToFP (v, sort, ctx=None)
 
def fpFPToFP (rm, v, sort, ctx=None)
 
def fpRealToFP (rm, v, sort, ctx=None)
 
def fpSignedToFP (rm, v, sort, ctx=None)
 
def fpUnsignedToFP (rm, v, sort, ctx=None)
 
def fpToFPUnsigned (rm, x, s, ctx=None)
 
def fpToSBV (rm, x, s, ctx=None)
 
def fpToUBV (rm, x, s, ctx=None)
 
def fpToReal (x, ctx=None)
 
def fpToIEEEBV (x, ctx=None)
 
def StringSort (ctx=None)
 
def CharSort (ctx=None)
 
def SeqSort (s)
 
def CharVal (ch, ctx=None)
 
def CharFromBv (ch, ctx=None)
 
def CharToBv (ch, ctx=None)
 
def CharToInt (ch, ctx=None)
 
def CharIsDigit (ch, ctx=None)
 
def is_seq (a)
 
def is_string (a)
 
def is_string_value (a)
 
def StringVal (s, ctx=None)
 
def String (name, ctx=None)
 
def Strings (names, ctx=None)
 
def SubString (s, offset, length)
 
def SubSeq (s, offset, length)
 
def Empty (s)
 
def Full (s)
 
def Unit (a)
 
def PrefixOf (a, b)
 
def SuffixOf (a, b)
 
def Contains (a, b)
 
def Replace (s, src, dst)
 
def IndexOf (s, substr, offset=None)
 
def LastIndexOf (s, substr)
 
def Length (s)
 
def StrToInt (s)
 
def IntToStr (s)
 
def StrToCode (s)
 
def StrFromCode (c)
 
def Re (s, ctx=None)
 
def ReSort (s)
 
def is_re (s)
 
def InRe (s, re)
 
def Union (*args)
 
def Intersect (*args)
 
def Plus (re)
 
def Option (re)
 
def Complement (re)
 
def Star (re)
 
def Loop (re, lo, hi=0)
 
def Range (lo, hi, ctx=None)
 
def Diff (a, b, ctx=None)
 
def AllChar (regex_sort, ctx=None)
 
def PartialOrder (a, index)
 
def LinearOrder (a, index)
 
def TreeOrder (a, index)
 
def PiecewiseLinearOrder (a, index)
 
def TransitiveClosure (f)
 
def to_Ast (ptr)
 
def to_ContextObj (ptr)
 
def to_AstVectorObj (ptr)
 
def on_clause_eh (ctx, p, clause)
 
def ensure_prop_closures ()
 
def user_prop_push (ctx, cb)
 
def user_prop_pop (ctx, cb, num_scopes)
 
def user_prop_fresh (ctx, _new_ctx)
 
def user_prop_fixed (ctx, cb, id, value)
 
def user_prop_created (ctx, cb, id)
 
def user_prop_final (ctx, cb)
 
def user_prop_eq (ctx, cb, x, y)
 
def user_prop_diseq (ctx, cb, x, y)
 
def user_prop_decide (ctx, cb, t_ref, idx_ref, phase_ref)
 
def PropagateFunction (name, *sig)
 

Variables

 Z3_DEBUG = __debug__
 
 sat = CheckSatResult(Z3_L_TRUE)
 
 unsat = CheckSatResult(Z3_L_FALSE)
 
 unknown = CheckSatResult(Z3_L_UNDEF)
 

Function Documentation

◆ Abs()

def z3py.Abs (   arg) 
Create the absolute value of an arithmetic expression

Definition at line 8932 of file z3py.py.

8932 def Abs(arg):
8933  """Create the absolute value of an arithmetic expression"""
8934  return If(arg > 0, arg, -arg)
8935 
8936 
z3py.Abs
def Abs(arg)
Definition: z3py.py:8932
z3py.If
def If(a, b, c, ctx=None)
Definition: z3py.py:1381

◆ AllChar()

def z3py.AllChar (   regex_sort,
  ctx = None 
) 
Create a regular expression that accepts all single character strings

Definition at line 11298 of file z3py.py.

11298 def AllChar(regex_sort, ctx=None):
11299  """Create a regular expression that accepts all single character strings
11300  """
11301  return ReRef(Z3_mk_re_allchar(regex_sort.ctx_ref(), regex_sort.ast), regex_sort.ctx)
11302 
11303 # Special Relations
11304 
11305 
Z3_mk_re_allchar
Z3_ast Z3_API Z3_mk_re_allchar(Z3_context c, Z3_sort regex_sort)
Create a regular expression that accepts all singleton sequences of the regular expression sort.
z3py.AllChar
def AllChar(regex_sort, ctx=None)
Definition: z3py.py:11298

◆ And()

def z3py.And ( args) 
Create a Z3 and-expression or and-probe.

>>> p, q, r = Bools('p q r')
>>> And(p, q, r)
And(p, q, r)
>>> P = BoolVector('p', 5)
>>> And(P)
And(p__0, p__1, p__2, p__3, p__4)

Definition at line 1849 of file z3py.py.

1849 def And(*args):
1850  """Create a Z3 and-expression or and-probe.
1851 
1852  >>> p, q, r = Bools('p q r')
1853  >>> And(p, q, r)
1854  And(p, q, r)
1855  >>> P = BoolVector('p', 5)
1856  >>> And(P)
1857  And(p__0, p__1, p__2, p__3, p__4)
1858  """
1859  last_arg = None
1860  if len(args) > 0:
1861  last_arg = args[len(args) - 1]
1862  if isinstance(last_arg, Context):
1863  ctx = args[len(args) - 1]
1864  args = args[:len(args) - 1]
1865  elif len(args) == 1 and isinstance(args[0], AstVector):
1866  ctx = args[0].ctx
1867  args = [a for a in args[0]]
1868  else:
1869  ctx = None
1870  args = _get_args(args)
1871  ctx = _get_ctx(_ctx_from_ast_arg_list(args, ctx))
1872  if z3_debug():
1873  _z3_assert(ctx is not None, "At least one of the arguments must be a Z3 expression or probe")
1874  if _has_probe(args):
1875  return _probe_and(args, ctx)
1876  else:
1877  args = _coerce_expr_list(args, ctx)
1878  _args, sz = _to_ast_array(args)
1879  return BoolRef(Z3_mk_and(ctx.ref(), sz, _args), ctx)
1880 
1881 
Z3_mk_and
Z3_ast Z3_API Z3_mk_and(Z3_context c, unsigned num_args, Z3_ast const args[])
Create an AST node representing args[0] and ... and args[num_args-1].
z3py.z3_debug
def z3_debug()
Definition: z3py.py:62
z3py.And
def And(*args)
Definition: z3py.py:1849

Referenced by Fixedpoint.add_rule(), Goal.as_expr(), Fixedpoint.query(), Fixedpoint.query_from_lvl(), and Fixedpoint.update_rule().

◆ AndThen()

def z3py.AndThen ( ts,
**  ks 
) 
Return a tactic that applies the tactics in `*ts` in sequence.

>>> x, y = Ints('x y')
>>> t = AndThen(Tactic('simplify'), Tactic('solve-eqs'))
>>> t(And(x == 0, y > x + 1))
[[Not(y <= 1)]]
>>> t(And(x == 0, y > x + 1)).as_expr()
Not(y <= 1)

Definition at line 8297 of file z3py.py.

8297 def AndThen(*ts, **ks):
8298  """Return a tactic that applies the tactics in `*ts` in sequence.
8299 
8300  >>> x, y = Ints('x y')
8301  >>> t = AndThen(Tactic('simplify'), Tactic('solve-eqs'))
8302  >>> t(And(x == 0, y > x + 1))
8303  [[Not(y <= 1)]]
8304  >>> t(And(x == 0, y > x + 1)).as_expr()
8305  Not(y <= 1)
8306  """
8307  if z3_debug():
8308  _z3_assert(len(ts) >= 2, "At least two arguments expected")
8309  ctx = ks.get("ctx", None)
8310  num = len(ts)
8311  r = ts[0]
8312  for i in range(num - 1):
8313  r = _and_then(r, ts[i + 1], ctx)
8314  return r
8315 
8316 
z3::range
expr range(expr const &lo, expr const &hi)
Definition: z3++.h:3970
z3py.AndThen
def AndThen(*ts, **ks)
Definition: z3py.py:8297

Referenced by Then().

◆ append_log()

def z3py.append_log (   s) 
Append user-defined string to interaction log.

Definition at line 119 of file z3py.py.

119 def append_log(s):
120  """Append user-defined string to interaction log. """
121  Z3_append_log(s)
122 
123 
Z3_append_log
void Z3_API Z3_append_log(Z3_string string)
Append user-defined string to interaction log.
z3py.append_log
def append_log(s)
Definition: z3py.py:119

◆ args2params()

def z3py.args2params (   arguments,
  keywords,
  ctx = None 
) 
Convert python arguments into a Z3_params object.
A ':' is added to the keywords, and '_' is replaced with '-'

>>> args2params(['model', True, 'relevancy', 2], {'elim_and' : True})
(params model true relevancy 2 elim_and true)

Definition at line 5466 of file z3py.py.

5466 def args2params(arguments, keywords, ctx=None):
5467  """Convert python arguments into a Z3_params object.
5468  A ':' is added to the keywords, and '_' is replaced with '-'
5469 
5470  >>> args2params(['model', True, 'relevancy', 2], {'elim_and' : True})
5471  (params model true relevancy 2 elim_and true)
5472  """
5473  if z3_debug():
5474  _z3_assert(len(arguments) % 2 == 0, "Argument list must have an even number of elements.")
5475  prev = None
5476  r = ParamsRef(ctx)
5477  for a in arguments:
5478  if prev is None:
5479  prev = a
5480  else:
5481  r.set(prev, a)
5482  prev = None
5483  for k in keywords:
5484  v = keywords[k]
5485  r.set(k, v)
5486  return r
5487 
5488 
z3py.args2params
def args2params(arguments, keywords, ctx=None)
Definition: z3py.py:5466

Referenced by Tactic.apply(), Solver.set(), Fixedpoint.set(), Optimize.set(), simplify(), and With().

◆ Array()

def z3py.Array (   name,
sorts 
) 
Return an array constant named `name` with the given domain and range sorts.

>>> a = Array('a', IntSort(), IntSort())
>>> a.sort()
Array(Int, Int)
>>> a[0]
a[0]

Definition at line 4733 of file z3py.py.

4733 def Array(name, *sorts):
4734  """Return an array constant named `name` with the given domain and range sorts.
4735 
4736  >>> a = Array('a', IntSort(), IntSort())
4737  >>> a.sort()
4738  Array(Int, Int)
4739  >>> a[0]
4740  a[0]
4741  """
4742  s = ArraySort(sorts)
4743  ctx = s.ctx
4744  return ArrayRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), s.ast), ctx)
4745 
4746 
Z3_mk_const
Z3_ast Z3_API Z3_mk_const(Z3_context c, Z3_symbol s, Z3_sort ty)
Declare and create a constant.
z3py.ArraySort
def ArraySort(*sig)
Definition: z3py.py:4700
z3py.Array
def Array(name, *sorts)
Definition: z3py.py:4733
z3py.to_symbol
def to_symbol(s, ctx=None)
Definition: z3py.py:124

◆ ArraySort()

def z3py.ArraySort ( sig) 
Return the Z3 array sort with the given domain and range sorts.

>>> A = ArraySort(IntSort(), BoolSort())
>>> A
Array(Int, Bool)
>>> A.domain()
Int
>>> A.range()
Bool
>>> AA = ArraySort(IntSort(), A)
>>> AA
Array(Int, Array(Int, Bool))

Definition at line 4700 of file z3py.py.

4700 def ArraySort(*sig):
4701  """Return the Z3 array sort with the given domain and range sorts.
4702 
4703  >>> A = ArraySort(IntSort(), BoolSort())
4704  >>> A
4705  Array(Int, Bool)
4706  >>> A.domain()
4707  Int
4708  >>> A.range()
4709  Bool
4710  >>> AA = ArraySort(IntSort(), A)
4711  >>> AA
4712  Array(Int, Array(Int, Bool))
4713  """
4714  sig = _get_args(sig)
4715  if z3_debug():
4716  _z3_assert(len(sig) > 1, "At least two arguments expected")
4717  arity = len(sig) - 1
4718  r = sig[arity]
4719  d = sig[0]
4720  if z3_debug():
4721  for s in sig:
4722  _z3_assert(is_sort(s), "Z3 sort expected")
4723  _z3_assert(s.ctx == r.ctx, "Context mismatch")
4724  ctx = d.ctx
4725  if len(sig) == 2:
4726  return ArraySortRef(Z3_mk_array_sort(ctx.ref(), d.ast, r.ast), ctx)
4727  dom = (Sort * arity)()
4728  for i in range(arity):
4729  dom[i] = sig[i].ast
4730  return ArraySortRef(Z3_mk_array_sort_n(ctx.ref(), arity, dom, r.ast), ctx)
4731 
4732 
Z3_mk_array_sort_n
Z3_sort Z3_API Z3_mk_array_sort_n(Z3_context c, unsigned n, Z3_sort const *domain, Z3_sort range)
Create an array type with N arguments.
Z3_mk_array_sort
Z3_sort Z3_API Z3_mk_array_sort(Z3_context c, Z3_sort domain, Z3_sort range)
Create an array type.
z3py.is_sort
def is_sort(s)
Definition: z3py.py:647

Referenced by Array(), Context.MkArraySort(), and SetSort().

◆ AtLeast()

def z3py.AtLeast ( args) 
Create an at-most Pseudo-Boolean k constraint.

>>> a, b, c = Bools('a b c')
>>> f = AtLeast(a, b, c, 2)

Definition at line 8955 of file z3py.py.

8955 def AtLeast(*args):
8956  """Create an at-most Pseudo-Boolean k constraint.
8957 
8958  >>> a, b, c = Bools('a b c')
8959  >>> f = AtLeast(a, b, c, 2)
8960  """
8961  args = _get_args(args)
8962  if z3_debug():
8963  _z3_assert(len(args) > 1, "Non empty list of arguments expected")
8964  ctx = _ctx_from_ast_arg_list(args)
8965  if z3_debug():
8966  _z3_assert(ctx is not None, "At least one of the arguments must be a Z3 expression")
8967  args1 = _coerce_expr_list(args[:-1], ctx)
8968  k = args[-1]
8969  _args, sz = _to_ast_array(args1)
8970  return BoolRef(Z3_mk_atleast(ctx.ref(), sz, _args, k), ctx)
8971 
8972 
Z3_mk_atleast
Z3_ast Z3_API Z3_mk_atleast(Z3_context c, unsigned num_args, Z3_ast const args[], unsigned k)
Pseudo-Boolean relations.
z3py.AtLeast
def AtLeast(*args)
Definition: z3py.py:8955

◆ AtMost()

def z3py.AtMost ( args) 
Create an at-most Pseudo-Boolean k constraint.

>>> a, b, c = Bools('a b c')
>>> f = AtMost(a, b, c, 2)

Definition at line 8937 of file z3py.py.

8937 def AtMost(*args):
8938  """Create an at-most Pseudo-Boolean k constraint.
8939 
8940  >>> a, b, c = Bools('a b c')
8941  >>> f = AtMost(a, b, c, 2)
8942  """
8943  args = _get_args(args)
8944  if z3_debug():
8945  _z3_assert(len(args) > 1, "Non empty list of arguments expected")
8946  ctx = _ctx_from_ast_arg_list(args)
8947  if z3_debug():
8948  _z3_assert(ctx is not None, "At least one of the arguments must be a Z3 expression")
8949  args1 = _coerce_expr_list(args[:-1], ctx)
8950  k = args[-1]
8951  _args, sz = _to_ast_array(args1)
8952  return BoolRef(Z3_mk_atmost(ctx.ref(), sz, _args, k), ctx)
8953 
8954 
Z3_mk_atmost
Z3_ast Z3_API Z3_mk_atmost(Z3_context c, unsigned num_args, Z3_ast const args[], unsigned k)
Pseudo-Boolean relations.
z3py.AtMost
def AtMost(*args)
Definition: z3py.py:8937

◆ BitVec()

def z3py.BitVec (   name,
  bv,
  ctx = None 
) 
Return a bit-vector constant named `name`. `bv` may be the number of bits of a bit-vector sort.
If `ctx=None`, then the global context is used.

>>> x  = BitVec('x', 16)
>>> is_bv(x)
True
>>> x.size()
16
>>> x.sort()
BitVec(16)
>>> word = BitVecSort(16)
>>> x2 = BitVec('x', word)
>>> eq(x, x2)
True

Definition at line 4037 of file z3py.py.

4037 def BitVec(name, bv, ctx=None):
4038  """Return a bit-vector constant named `name`. `bv` may be the number of bits of a bit-vector sort.
4039  If `ctx=None`, then the global context is used.
4040 
4041  >>> x = BitVec('x', 16)
4042  >>> is_bv(x)
4043  True
4044  >>> x.size()
4045  16
4046  >>> x.sort()
4047  BitVec(16)
4048  >>> word = BitVecSort(16)
4049  >>> x2 = BitVec('x', word)
4050  >>> eq(x, x2)
4051  True
4052  """
4053  if isinstance(bv, BitVecSortRef):
4054  ctx = bv.ctx
4055  else:
4056  ctx = _get_ctx(ctx)
4057  bv = BitVecSort(bv, ctx)
4058  return BitVecRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), bv.ast), ctx)
4059 
4060 
z3py.BitVec
def BitVec(name, bv, ctx=None)
Definition: z3py.py:4037
z3py.BitVecSort
def BitVecSort(sz, ctx=None)
Definition: z3py.py:4005

Referenced by BitVecs().

◆ BitVecs()

def z3py.BitVecs (   names,
  bv,
  ctx = None 
) 
Return a tuple of bit-vector constants of size bv.

>>> x, y, z = BitVecs('x y z', 16)
>>> x.size()
16
>>> x.sort()
BitVec(16)
>>> Sum(x, y, z)
0 + x + y + z
>>> Product(x, y, z)
1*x*y*z
>>> simplify(Product(x, y, z))
x*y*z

Definition at line 4061 of file z3py.py.

4061 def BitVecs(names, bv, ctx=None):
4062  """Return a tuple of bit-vector constants of size bv.
4063 
4064  >>> x, y, z = BitVecs('x y z', 16)
4065  >>> x.size()
4066  16
4067  >>> x.sort()
4068  BitVec(16)
4069  >>> Sum(x, y, z)
4070  0 + x + y + z
4071  >>> Product(x, y, z)
4072  1*x*y*z
4073  >>> simplify(Product(x, y, z))
4074  x*y*z
4075  """
4076  ctx = _get_ctx(ctx)
4077  if isinstance(names, str):
4078  names = names.split(" ")
4079  return [BitVec(name, bv, ctx) for name in names]
4080 
4081 
z3py.BitVecs
def BitVecs(names, bv, ctx=None)
Definition: z3py.py:4061

◆ BitVecSort()

def z3py.BitVecSort (   sz,
  ctx = None 
) 
Return a Z3 bit-vector sort of the given size. If `ctx=None`, then the global context is used.

>>> Byte = BitVecSort(8)
>>> Word = BitVecSort(16)
>>> Byte
BitVec(8)
>>> x = Const('x', Byte)
>>> eq(x, BitVec('x', 8))
True

Definition at line 4005 of file z3py.py.

4005 def BitVecSort(sz, ctx=None):
4006  """Return a Z3 bit-vector sort of the given size. If `ctx=None`, then the global context is used.
4007 
4008  >>> Byte = BitVecSort(8)
4009  >>> Word = BitVecSort(16)
4010  >>> Byte
4011  BitVec(8)
4012  >>> x = Const('x', Byte)
4013  >>> eq(x, BitVec('x', 8))
4014  True
4015  """
4016  ctx = _get_ctx(ctx)
4017  return BitVecSortRef(Z3_mk_bv_sort(ctx.ref(), sz), ctx)
4018 
4019 
Z3_mk_bv_sort
Z3_sort Z3_API Z3_mk_bv_sort(Z3_context c, unsigned sz)
Create a bit-vector type of the given size.

Referenced by BitVec(), BitVecVal(), Context.mkBitVecSort(), and Context.MkBitVecSort().

◆ BitVecVal()

def z3py.BitVecVal (   val,
  bv,
  ctx = None 
) 
Return a bit-vector value with the given number of bits. If `ctx=None`, then the global context is used.

>>> v = BitVecVal(10, 32)
>>> v
10
>>> print("0x%.8x" % v.as_long())
0x0000000a

Definition at line 4020 of file z3py.py.

4020 def BitVecVal(val, bv, ctx=None):
4021  """Return a bit-vector value with the given number of bits. If `ctx=None`, then the global context is used.
4022 
4023  >>> v = BitVecVal(10, 32)
4024  >>> v
4025  10
4026  >>> print("0x%.8x" % v.as_long())
4027  0x0000000a
4028  """
4029  if is_bv_sort(bv):
4030  ctx = bv.ctx
4031  return BitVecNumRef(Z3_mk_numeral(ctx.ref(), _to_int_str(val), bv.ast), ctx)
4032  else:
4033  ctx = _get_ctx(ctx)
4034  return BitVecNumRef(Z3_mk_numeral(ctx.ref(), _to_int_str(val), BitVecSort(bv, ctx).ast), ctx)
4035 
4036 
Z3_mk_numeral
Z3_ast Z3_API Z3_mk_numeral(Z3_context c, Z3_string numeral, Z3_sort ty)
Create a numeral of a given sort.
z3py.is_bv_sort
def is_bv_sort(s)
Definition: z3py.py:3476
z3py.BitVecVal
def BitVecVal(val, bv, ctx=None)
Definition: z3py.py:4020

◆ Bool()

def z3py.Bool (   name,
  ctx = None 
) 
Return a Boolean constant named `name`. If `ctx=None`, then the global context is used.

>>> p = Bool('p')
>>> q = Bool('q')
>>> And(p, q)
And(p, q)

Definition at line 1728 of file z3py.py.

1728 def Bool(name, ctx=None):
1729  """Return a Boolean constant named `name`. If `ctx=None`, then the global context is used.
1730 
1731  >>> p = Bool('p')
1732  >>> q = Bool('q')
1733  >>> And(p, q)
1734  And(p, q)
1735  """
1736  ctx = _get_ctx(ctx)
1737  return BoolRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), BoolSort(ctx).ast), ctx)
1738 
1739 
z3py.BoolSort
def BoolSort(ctx=None)
Definition: z3py.py:1691
z3py.Bool
def Bool(name, ctx=None)
Definition: z3py.py:1728

Referenced by Solver.assert_and_track(), Optimize.assert_and_track(), Bools(), and BoolVector().

◆ Bools()

def z3py.Bools (   names,
  ctx = None 
) 
Return a tuple of Boolean constants.

`names` is a single string containing all names separated by blank spaces.
If `ctx=None`, then the global context is used.

>>> p, q, r = Bools('p q r')
>>> And(p, Or(q, r))
And(p, Or(q, r))

Definition at line 1740 of file z3py.py.

1740 def Bools(names, ctx=None):
1741  """Return a tuple of Boolean constants.
1742 
1743  `names` is a single string containing all names separated by blank spaces.
1744  If `ctx=None`, then the global context is used.
1745 
1746  >>> p, q, r = Bools('p q r')
1747  >>> And(p, Or(q, r))
1748  And(p, Or(q, r))
1749  """
1750  ctx = _get_ctx(ctx)
1751  if isinstance(names, str):
1752  names = names.split(" ")
1753  return [Bool(name, ctx) for name in names]
1754 
1755 
z3py.Bools
def Bools(names, ctx=None)
Definition: z3py.py:1740

◆ BoolSort()

def z3py.BoolSort (   ctx = None) 
Return the Boolean Z3 sort. If `ctx=None`, then the global context is used.

>>> BoolSort()
Bool
>>> p = Const('p', BoolSort())
>>> is_bool(p)
True
>>> r = Function('r', IntSort(), IntSort(), BoolSort())
>>> r(0, 1)
r(0, 1)
>>> is_bool(r(0, 1))
True

Definition at line 1691 of file z3py.py.

1691 def BoolSort(ctx=None):
1692  """Return the Boolean Z3 sort. If `ctx=None`, then the global context is used.
1693 
1694  >>> BoolSort()
1695  Bool
1696  >>> p = Const('p', BoolSort())
1697  >>> is_bool(p)
1698  True
1699  >>> r = Function('r', IntSort(), IntSort(), BoolSort())
1700  >>> r(0, 1)
1701  r(0, 1)
1702  >>> is_bool(r(0, 1))
1703  True
1704  """
1705  ctx = _get_ctx(ctx)
1706  return BoolSortRef(Z3_mk_bool_sort(ctx.ref()), ctx)
1707 
1708 
Z3_mk_bool_sort
Z3_sort Z3_API Z3_mk_bool_sort(Z3_context c)
Create the Boolean type.

Referenced by Goal.assert_exprs(), Solver.assert_exprs(), Fixedpoint.assert_exprs(), Optimize.assert_exprs(), Bool(), Solver.check(), FreshBool(), Context.getBoolSort(), If(), Implies(), Context.mkBoolSort(), Not(), SetSort(), QuantifierRef.sort(), and Xor().

◆ BoolVal()

def z3py.BoolVal (   val,
  ctx = None 
) 
Return the Boolean value `True` or `False`. If `ctx=None`, then the global context is used.

>>> BoolVal(True)
True
>>> is_true(BoolVal(True))
True
>>> is_true(True)
False
>>> is_false(BoolVal(False))
True

Definition at line 1709 of file z3py.py.

1709 def BoolVal(val, ctx=None):
1710  """Return the Boolean value `True` or `False`. If `ctx=None`, then the global context is used.
1711 
1712  >>> BoolVal(True)
1713  True
1714  >>> is_true(BoolVal(True))
1715  True
1716  >>> is_true(True)
1717  False
1718  >>> is_false(BoolVal(False))
1719  True
1720  """
1721  ctx = _get_ctx(ctx)
1722  if val:
1723  return BoolRef(Z3_mk_true(ctx.ref()), ctx)
1724  else:
1725  return BoolRef(Z3_mk_false(ctx.ref()), ctx)
1726 
1727 
Z3_mk_true
Z3_ast Z3_API Z3_mk_true(Z3_context c)
Create an AST node representing true.
Z3_mk_false
Z3_ast Z3_API Z3_mk_false(Z3_context c)
Create an AST node representing false.
z3py.BoolVal
def BoolVal(val, ctx=None)
Definition: z3py.py:1709

Referenced by Goal.as_expr(), ApplyResult.as_expr(), BoolSortRef.cast(), UserPropagateBase.conflict(), AlgebraicNumRef.index(), is_quantifier(), and Solver.to_smt2().

◆ BoolVector()

def z3py.BoolVector (   prefix,
  sz,
  ctx = None 
) 
Return a list of Boolean constants of size `sz`.

The constants are named using the given prefix.
If `ctx=None`, then the global context is used.

>>> P = BoolVector('p', 3)
>>> P
[p__0, p__1, p__2]
>>> And(P)
And(p__0, p__1, p__2)

Definition at line 1756 of file z3py.py.

1756 def BoolVector(prefix, sz, ctx=None):
1757  """Return a list of Boolean constants of size `sz`.
1758 
1759  The constants are named using the given prefix.
1760  If `ctx=None`, then the global context is used.
1761 
1762  >>> P = BoolVector('p', 3)
1763  >>> P
1764  [p__0, p__1, p__2]
1765  >>> And(P)
1766  And(p__0, p__1, p__2)
1767  """
1768  return [Bool("%s__%s" % (prefix, i)) for i in range(sz)]
1769 
1770 
z3py.BoolVector
def BoolVector(prefix, sz, ctx=None)
Definition: z3py.py:1756

◆ BV2Int()

def z3py.BV2Int (   a,
  is_signed = False 
) 
Return the Z3 expression BV2Int(a).

>>> b = BitVec('b', 3)
>>> BV2Int(b).sort()
Int
>>> x = Int('x')
>>> x > BV2Int(b)
x > BV2Int(b)
>>> x > BV2Int(b, is_signed=False)
x > BV2Int(b)
>>> x > BV2Int(b, is_signed=True)
x > If(b < 0, BV2Int(b) - 8, BV2Int(b))
>>> solve(x > BV2Int(b), b == 1, x < 3)
[x = 2, b = 1]

Definition at line 3973 of file z3py.py.

3973 def BV2Int(a, is_signed=False):
3974  """Return the Z3 expression BV2Int(a).
3975 
3976  >>> b = BitVec('b', 3)
3977  >>> BV2Int(b).sort()
3978  Int
3979  >>> x = Int('x')
3980  >>> x > BV2Int(b)
3981  x > BV2Int(b)
3982  >>> x > BV2Int(b, is_signed=False)
3983  x > BV2Int(b)
3984  >>> x > BV2Int(b, is_signed=True)
3985  x > If(b < 0, BV2Int(b) - 8, BV2Int(b))
3986  >>> solve(x > BV2Int(b), b == 1, x < 3)
3987  [x = 2, b = 1]
3988  """
3989  if z3_debug():
3990  _z3_assert(is_bv(a), "First argument must be a Z3 bit-vector expression")
3991  ctx = a.ctx
3992  # investigate problem with bv2int
3993  return ArithRef(Z3_mk_bv2int(ctx.ref(), a.as_ast(), is_signed), ctx)
3994 
3995 
Z3_mk_bv2int
Z3_ast Z3_API Z3_mk_bv2int(Z3_context c, Z3_ast t1, bool is_signed)
Create an integer from the bit-vector argument t1. If is_signed is false, then the bit-vector t1 is t...
z3py.is_bv
def is_bv(a)
Definition: z3py.py:3944
z3py.BV2Int
def BV2Int(a, is_signed=False)
Definition: z3py.py:3973

◆ BVAddNoOverflow()

def z3py.BVAddNoOverflow (   a,
  b,
  signed 
) 
A predicate the determines that bit-vector addition does not overflow

Definition at line 4459 of file z3py.py.

4459 def BVAddNoOverflow(a, b, signed):
4460  """A predicate the determines that bit-vector addition does not overflow"""
4461  _check_bv_args(a, b)
4462  a, b = _coerce_exprs(a, b)
4463  return BoolRef(Z3_mk_bvadd_no_overflow(a.ctx_ref(), a.as_ast(), b.as_ast(), signed), a.ctx)
4464 
4465 
Z3_mk_bvadd_no_overflow
Z3_ast Z3_API Z3_mk_bvadd_no_overflow(Z3_context c, Z3_ast t1, Z3_ast t2, bool is_signed)
Create a predicate that checks that the bit-wise addition of t1 and t2 does not overflow.
z3py.BVAddNoOverflow
def BVAddNoOverflow(a, b, signed)
Definition: z3py.py:4459

◆ BVAddNoUnderflow()

def z3py.BVAddNoUnderflow (   a,
  b 
) 
A predicate the determines that signed bit-vector addition does not underflow

Definition at line 4466 of file z3py.py.

4466 def BVAddNoUnderflow(a, b):
4467  """A predicate the determines that signed bit-vector addition does not underflow"""
4468  _check_bv_args(a, b)
4469  a, b = _coerce_exprs(a, b)
4470  return BoolRef(Z3_mk_bvadd_no_underflow(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4471 
4472 
Z3_mk_bvadd_no_underflow
Z3_ast Z3_API Z3_mk_bvadd_no_underflow(Z3_context c, Z3_ast t1, Z3_ast t2)
Create a predicate that checks that the bit-wise signed addition of t1 and t2 does not underflow.
z3py.BVAddNoUnderflow
def BVAddNoUnderflow(a, b)
Definition: z3py.py:4466

◆ BVMulNoOverflow()

def z3py.BVMulNoOverflow (   a,
  b,
  signed 
) 
A predicate the determines that bit-vector multiplication does not overflow

Definition at line 4501 of file z3py.py.

4501 def BVMulNoOverflow(a, b, signed):
4502  """A predicate the determines that bit-vector multiplication does not overflow"""
4503  _check_bv_args(a, b)
4504  a, b = _coerce_exprs(a, b)
4505  return BoolRef(Z3_mk_bvmul_no_overflow(a.ctx_ref(), a.as_ast(), b.as_ast(), signed), a.ctx)
4506 
4507 
Z3_mk_bvmul_no_overflow
Z3_ast Z3_API Z3_mk_bvmul_no_overflow(Z3_context c, Z3_ast t1, Z3_ast t2, bool is_signed)
Create a predicate that checks that the bit-wise multiplication of t1 and t2 does not overflow.
z3py.BVMulNoOverflow
def BVMulNoOverflow(a, b, signed)
Definition: z3py.py:4501

◆ BVMulNoUnderflow()

def z3py.BVMulNoUnderflow (   a,
  b 
) 
A predicate the determines that bit-vector signed multiplication does not underflow

Definition at line 4508 of file z3py.py.

4508 def BVMulNoUnderflow(a, b):
4509  """A predicate the determines that bit-vector signed multiplication does not underflow"""
4510  _check_bv_args(a, b)
4511  a, b = _coerce_exprs(a, b)
4512  return BoolRef(Z3_mk_bvmul_no_underflow(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4513 
4514 
Z3_mk_bvmul_no_underflow
Z3_ast Z3_API Z3_mk_bvmul_no_underflow(Z3_context c, Z3_ast t1, Z3_ast t2)
Create a predicate that checks that the bit-wise signed multiplication of t1 and t2 does not underflo...
z3py.BVMulNoUnderflow
def BVMulNoUnderflow(a, b)
Definition: z3py.py:4508

◆ BVRedAnd()

def z3py.BVRedAnd (   a) 
Return the reduction-and expression of `a`.

Definition at line 4445 of file z3py.py.

4445 def BVRedAnd(a):
4446  """Return the reduction-and expression of `a`."""
4447  if z3_debug():
4448  _z3_assert(is_bv(a), "First argument must be a Z3 bit-vector expression")
4449  return BitVecRef(Z3_mk_bvredand(a.ctx_ref(), a.as_ast()), a.ctx)
4450 
4451 
Z3_mk_bvredand
Z3_ast Z3_API Z3_mk_bvredand(Z3_context c, Z3_ast t1)
Take conjunction of bits in vector, return vector of length 1.
z3py.BVRedAnd
def BVRedAnd(a)
Definition: z3py.py:4445

◆ BVRedOr()

def z3py.BVRedOr (   a) 
Return the reduction-or expression of `a`.

Definition at line 4452 of file z3py.py.

4452 def BVRedOr(a):
4453  """Return the reduction-or expression of `a`."""
4454  if z3_debug():
4455  _z3_assert(is_bv(a), "First argument must be a Z3 bit-vector expression")
4456  return BitVecRef(Z3_mk_bvredor(a.ctx_ref(), a.as_ast()), a.ctx)
4457 
4458 
Z3_mk_bvredor
Z3_ast Z3_API Z3_mk_bvredor(Z3_context c, Z3_ast t1)
Take disjunction of bits in vector, return vector of length 1.
z3py.BVRedOr
def BVRedOr(a)
Definition: z3py.py:4452

◆ BVSDivNoOverflow()

def z3py.BVSDivNoOverflow (   a,
  b 
) 
A predicate the determines that bit-vector signed division does not overflow

Definition at line 4487 of file z3py.py.

4487 def BVSDivNoOverflow(a, b):
4488  """A predicate the determines that bit-vector signed division does not overflow"""
4489  _check_bv_args(a, b)
4490  a, b = _coerce_exprs(a, b)
4491  return BoolRef(Z3_mk_bvsdiv_no_overflow(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4492 
4493 
Z3_mk_bvsdiv_no_overflow
Z3_ast Z3_API Z3_mk_bvsdiv_no_overflow(Z3_context c, Z3_ast t1, Z3_ast t2)
Create a predicate that checks that the bit-wise signed division of t1 and t2 does not overflow.
z3py.BVSDivNoOverflow
def BVSDivNoOverflow(a, b)
Definition: z3py.py:4487

◆ BVSNegNoOverflow()

def z3py.BVSNegNoOverflow (   a) 
A predicate the determines that bit-vector unary negation does not overflow

Definition at line 4494 of file z3py.py.

4494 def BVSNegNoOverflow(a):
4495  """A predicate the determines that bit-vector unary negation does not overflow"""
4496  if z3_debug():
4497  _z3_assert(is_bv(a), "First argument must be a Z3 bit-vector expression")
4498  return BoolRef(Z3_mk_bvneg_no_overflow(a.ctx_ref(), a.as_ast()), a.ctx)
4499 
4500 
Z3_mk_bvneg_no_overflow
Z3_ast Z3_API Z3_mk_bvneg_no_overflow(Z3_context c, Z3_ast t1)
Check that bit-wise negation does not overflow when t1 is interpreted as a signed bit-vector.
z3py.BVSNegNoOverflow
def BVSNegNoOverflow(a)
Definition: z3py.py:4494

◆ BVSubNoOverflow()

def z3py.BVSubNoOverflow (   a,
  b 
) 
A predicate the determines that bit-vector subtraction does not overflow

Definition at line 4473 of file z3py.py.

4473 def BVSubNoOverflow(a, b):
4474  """A predicate the determines that bit-vector subtraction does not overflow"""
4475  _check_bv_args(a, b)
4476  a, b = _coerce_exprs(a, b)
4477  return BoolRef(Z3_mk_bvsub_no_overflow(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4478 
4479 
Z3_mk_bvsub_no_overflow
Z3_ast Z3_API Z3_mk_bvsub_no_overflow(Z3_context c, Z3_ast t1, Z3_ast t2)
Create a predicate that checks that the bit-wise signed subtraction of t1 and t2 does not overflow.
z3py.BVSubNoOverflow
def BVSubNoOverflow(a, b)
Definition: z3py.py:4473

◆ BVSubNoUnderflow()

def z3py.BVSubNoUnderflow (   a,
  b,
  signed 
) 
A predicate the determines that bit-vector subtraction does not underflow

Definition at line 4480 of file z3py.py.

4480 def BVSubNoUnderflow(a, b, signed):
4481  """A predicate the determines that bit-vector subtraction does not underflow"""
4482  _check_bv_args(a, b)
4483  a, b = _coerce_exprs(a, b)
4484  return BoolRef(Z3_mk_bvsub_no_underflow(a.ctx_ref(), a.as_ast(), b.as_ast(), signed), a.ctx)
4485 
4486 
Z3_mk_bvsub_no_underflow
Z3_ast Z3_API Z3_mk_bvsub_no_underflow(Z3_context c, Z3_ast t1, Z3_ast t2, bool is_signed)
Create a predicate that checks that the bit-wise subtraction of t1 and t2 does not underflow.
z3py.BVSubNoUnderflow
def BVSubNoUnderflow(a, b, signed)
Definition: z3py.py:4480

◆ Cbrt()

def z3py.Cbrt (   a,
  ctx = None 
) 
 Return a Z3 expression which represents the cubic root of a.

>>> x = Real('x')
>>> Cbrt(x)
x**(1/3)

Definition at line 3424 of file z3py.py.

3424 def Cbrt(a, ctx=None):
3425  """ Return a Z3 expression which represents the cubic root of a.
3426 
3427  >>> x = Real('x')
3428  >>> Cbrt(x)
3429  x**(1/3)
3430  """
3431  if not is_expr(a):
3432  ctx = _get_ctx(ctx)
3433  a = RealVal(a, ctx)
3434  return a ** "1/3"
3435 
z3py.is_expr
def is_expr(a)
Definition: z3py.py:1242
z3py.Cbrt
def Cbrt(a, ctx=None)
Definition: z3py.py:3424
z3py.RealVal
def RealVal(val, ctx=None)
Definition: z3py.py:3200

◆ CharFromBv()

def z3py.CharFromBv (   ch,
  ctx = None 
)

Definition at line 10856 of file z3py.py.

10856 def CharFromBv(ch, ctx=None):
10857  if not is_expr(ch):
10858  raise Z3Expression("Bit-vector expression needed")
10859  return _to_expr_ref(Z3_mk_char_from_bv(ch.ctx_ref(), ch.as_ast()), ch.ctx)
10860 
Z3_mk_char_from_bv
Z3_ast Z3_API Z3_mk_char_from_bv(Z3_context c, Z3_ast bv)
Create a character from a bit-vector (code point).
z3py.CharFromBv
def CharFromBv(ch, ctx=None)
Definition: z3py.py:10856

◆ CharIsDigit()

def z3py.CharIsDigit (   ch,
  ctx = None 
)

Definition at line 10869 of file z3py.py.

10869 def CharIsDigit(ch, ctx=None):
10870  ch = _coerce_char(ch, ctx)
10871  return ch.is_digit()
10872 
z3py.CharIsDigit
def CharIsDigit(ch, ctx=None)
Definition: z3py.py:10869

◆ CharSort()

def z3py.CharSort (   ctx = None) 
Create a character sort
>>> ch = CharSort()
>>> print(ch)
Char

Definition at line 10755 of file z3py.py.

10755 def CharSort(ctx=None):
10756  """Create a character sort
10757  >>> ch = CharSort()
10758  >>> print(ch)
10759  Char
10760  """
10761  ctx = _get_ctx(ctx)
10762  return CharSortRef(Z3_mk_char_sort(ctx.ref()), ctx)
10763 
10764 
Z3_mk_char_sort
Z3_sort Z3_API Z3_mk_char_sort(Z3_context c)
Create a sort for unicode characters.
z3py.CharSort
def CharSort(ctx=None)
Definition: z3py.py:10755

Referenced by Context.mkCharSort().

◆ CharToBv()

def z3py.CharToBv (   ch,
  ctx = None 
)

Definition at line 10861 of file z3py.py.

10861 def CharToBv(ch, ctx=None):
10862  ch = _coerce_char(ch, ctx)
10863  return ch.to_bv()
10864 
z3py.CharToBv
def CharToBv(ch, ctx=None)
Definition: z3py.py:10861

◆ CharToInt()

def z3py.CharToInt (   ch,
  ctx = None 
)

Definition at line 10865 of file z3py.py.

10865 def CharToInt(ch, ctx=None):
10866  ch = _coerce_char(ch, ctx)
10867  return ch.to_int()
10868 
z3py.CharToInt
def CharToInt(ch, ctx=None)
Definition: z3py.py:10865

◆ CharVal()

def z3py.CharVal (   ch,
  ctx = None 
)

Definition at line 10848 of file z3py.py.

10848 def CharVal(ch, ctx=None):
10849  ctx = _get_ctx(ctx)
10850  if isinstance(ch, str):
10851  ch = ord(ch)
10852  if not isinstance(ch, int):
10853  raise Z3Exception("character value should be an ordinal")
10854  return _to_expr_ref(Z3_mk_char(ctx.ref(), ch), ctx)
10855 
Z3_mk_char
Z3_ast Z3_API Z3_mk_char(Z3_context c, unsigned ch)
Create a character literal.
z3py.CharVal
def CharVal(ch, ctx=None)
Definition: z3py.py:10848

Referenced by SeqRef.__gt__().

◆ Complement()

def z3py.Complement (   re) 
Create the complement regular expression.

Definition at line 11250 of file z3py.py.

11250 def Complement(re):
11251  """Create the complement regular expression."""
11252  return ReRef(Z3_mk_re_complement(re.ctx_ref(), re.as_ast()), re.ctx)
11253 
11254 
Z3_mk_re_complement
Z3_ast Z3_API Z3_mk_re_complement(Z3_context c, Z3_ast re)
Create the complement of the regular language re.
z3py.Complement
def Complement(re)
Definition: z3py.py:11250

◆ Concat()

def z3py.Concat ( args) 
Create a Z3 bit-vector concatenation expression.

>>> v = BitVecVal(1, 4)
>>> Concat(v, v+1, v)
Concat(Concat(1, 1 + 1), 1)
>>> simplify(Concat(v, v+1, v))
289
>>> print("%.3x" % simplify(Concat(v, v+1, v)).as_long())
121

Definition at line 4082 of file z3py.py.

4082 def Concat(*args):
4083  """Create a Z3 bit-vector concatenation expression.
4084 
4085  >>> v = BitVecVal(1, 4)
4086  >>> Concat(v, v+1, v)
4087  Concat(Concat(1, 1 + 1), 1)
4088  >>> simplify(Concat(v, v+1, v))
4089  289
4090  >>> print("%.3x" % simplify(Concat(v, v+1, v)).as_long())
4091  121
4092  """
4093  args = _get_args(args)
4094  sz = len(args)
4095  if z3_debug():
4096  _z3_assert(sz >= 2, "At least two arguments expected.")
4097 
4098  ctx = None
4099  for a in args:
4100  if is_expr(a):
4101  ctx = a.ctx
4102  break
4103  if is_seq(args[0]) or isinstance(args[0], str):
4104  args = [_coerce_seq(s, ctx) for s in args]
4105  if z3_debug():
4106  _z3_assert(all([is_seq(a) for a in args]), "All arguments must be sequence expressions.")
4107  v = (Ast * sz)()
4108  for i in range(sz):
4109  v[i] = args[i].as_ast()
4110  return SeqRef(Z3_mk_seq_concat(ctx.ref(), sz, v), ctx)
4111 
4112  if is_re(args[0]):
4113  if z3_debug():
4114  _z3_assert(all([is_re(a) for a in args]), "All arguments must be regular expressions.")
4115  v = (Ast * sz)()
4116  for i in range(sz):
4117  v[i] = args[i].as_ast()
4118  return ReRef(Z3_mk_re_concat(ctx.ref(), sz, v), ctx)
4119 
4120  if z3_debug():
4121  _z3_assert(all([is_bv(a) for a in args]), "All arguments must be Z3 bit-vector expressions.")
4122  r = args[0]
4123  for i in range(sz - 1):
4124  r = BitVecRef(Z3_mk_concat(ctx.ref(), r.as_ast(), args[i + 1].as_ast()), ctx)
4125  return r
4126 
4127 
Z3_mk_seq_concat
Z3_ast Z3_API Z3_mk_seq_concat(Z3_context c, unsigned n, Z3_ast const args[])
Concatenate sequences.
Z3_mk_re_concat
Z3_ast Z3_API Z3_mk_re_concat(Z3_context c, unsigned n, Z3_ast const args[])
Create the concatenation of the regular languages.
Z3_mk_concat
Z3_ast Z3_API Z3_mk_concat(Z3_context c, Z3_ast t1, Z3_ast t2)
Concatenate the given bit-vectors.
z3py.Concat
def Concat(*args)
Definition: z3py.py:4082
z3py.is_seq
def is_seq(a)
Definition: z3py.py:10894
z3py.is_re
def is_re(s)
Definition: z3py.py:11168

Referenced by SeqRef.__add__(), and SeqRef.__radd__().

◆ Cond()

def z3py.Cond (   p,
  t1,
  t2,
  ctx = None 
) 
Return a tactic that applies tactic `t1` to a goal if probe `p` evaluates to true, and `t2` otherwise.

>>> t = Cond(Probe('is-qfnra'), Tactic('qfnra'), Tactic('smt'))

Definition at line 8754 of file z3py.py.

8754 def Cond(p, t1, t2, ctx=None):
8755  """Return a tactic that applies tactic `t1` to a goal if probe `p` evaluates to true, and `t2` otherwise.
8756 
8757  >>> t = Cond(Probe('is-qfnra'), Tactic('qfnra'), Tactic('smt'))
8758  """
8759  p = _to_probe(p, ctx)
8760  t1 = _to_tactic(t1, ctx)
8761  t2 = _to_tactic(t2, ctx)
8762  return Tactic(Z3_tactic_cond(t1.ctx.ref(), p.probe, t1.tactic, t2.tactic), t1.ctx)
8763 
Z3_tactic_cond
Z3_tactic Z3_API Z3_tactic_cond(Z3_context c, Z3_probe p, Z3_tactic t1, Z3_tactic t2)
Return a tactic that applies t1 to a given goal if the probe p evaluates to true, and t2 if p evaluat...
z3py.Cond
def Cond(p, t1, t2, ctx=None)
Definition: z3py.py:8754

Referenced by If().

◆ Const()

def z3py.Const (   name,
  sort 
) 
Create a constant of the given sort.

>>> Const('x', IntSort())
x

Definition at line 1437 of file z3py.py.

1437 def Const(name, sort):
1438  """Create a constant of the given sort.
1439 
1440  >>> Const('x', IntSort())
1441  x
1442  """
1443  if z3_debug():
1444  _z3_assert(isinstance(sort, SortRef), "Z3 sort expected")
1445  ctx = sort.ctx
1446  return _to_expr_ref(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), sort.ast), ctx)
1447 
1448 
z3py.Const
def Const(name, sort)
Definition: z3py.py:1437

Referenced by Consts().

◆ Consts()

def z3py.Consts (   names,
  sort 
) 
Create several constants of the given sort.

`names` is a string containing the names of all constants to be created.
Blank spaces separate the names of different constants.

>>> x, y, z = Consts('x y z', IntSort())
>>> x + y + z
x + y + z

Definition at line 1449 of file z3py.py.

1449 def Consts(names, sort):
1450  """Create several constants of the given sort.
1451 
1452  `names` is a string containing the names of all constants to be created.
1453  Blank spaces separate the names of different constants.
1454 
1455  >>> x, y, z = Consts('x y z', IntSort())
1456  >>> x + y + z
1457  x + y + z
1458  """
1459  if isinstance(names, str):
1460  names = names.split(" ")
1461  return [Const(name, sort) for name in names]
1462 
1463 
z3py.Consts
def Consts(names, sort)
Definition: z3py.py:1449

◆ Contains()

def z3py.Contains (   a,
  b 
) 
Check if 'a' contains 'b'
>>> s1 = Contains("abc", "ab")
>>> simplify(s1)
True
>>> s2 = Contains("abc", "bc")
>>> simplify(s2)
True
>>> x, y, z = Strings('x y z')
>>> s3 = Contains(Concat(x,y,z), y)
>>> simplify(s3)
True

Definition at line 11025 of file z3py.py.

11025 def Contains(a, b):
11026  """Check if 'a' contains 'b'
11027  >>> s1 = Contains("abc", "ab")
11028  >>> simplify(s1)
11029  True
11030  >>> s2 = Contains("abc", "bc")
11031  >>> simplify(s2)
11032  True
11033  >>> x, y, z = Strings('x y z')
11034  >>> s3 = Contains(Concat(x,y,z), y)
11035  >>> simplify(s3)
11036  True
11037  """
11038  ctx = _get_ctx2(a, b)
11039  a = _coerce_seq(a, ctx)
11040  b = _coerce_seq(b, ctx)
11041  return BoolRef(Z3_mk_seq_contains(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
11042 
11043 
Z3_mk_seq_contains
Z3_ast Z3_API Z3_mk_seq_contains(Z3_context c, Z3_ast container, Z3_ast containee)
Check if container contains containee.
z3py.Contains
def Contains(a, b)
Definition: z3py.py:11025

◆ CreateDatatypes()

def z3py.CreateDatatypes ( ds) 
Create mutually recursive Z3 datatypes using 1 or more Datatype helper objects.

In the following example we define a Tree-List using two mutually recursive datatypes.

>>> TreeList = Datatype('TreeList')
>>> Tree     = Datatype('Tree')
>>> # Tree has two constructors: leaf and node
>>> Tree.declare('leaf', ('val', IntSort()))
>>> # a node contains a list of trees
>>> Tree.declare('node', ('children', TreeList))
>>> TreeList.declare('nil')
>>> TreeList.declare('cons', ('car', Tree), ('cdr', TreeList))
>>> Tree, TreeList = CreateDatatypes(Tree, TreeList)
>>> Tree.val(Tree.leaf(10))
val(leaf(10))
>>> simplify(Tree.val(Tree.leaf(10)))
10
>>> n1 = Tree.node(TreeList.cons(Tree.leaf(10), TreeList.cons(Tree.leaf(20), TreeList.nil)))
>>> n1
node(cons(leaf(10), cons(leaf(20), nil)))
>>> n2 = Tree.node(TreeList.cons(n1, TreeList.nil))
>>> simplify(n2 == n1)
False
>>> simplify(TreeList.car(Tree.children(n2)) == n1)
True

Definition at line 5158 of file z3py.py.

5158 def CreateDatatypes(*ds):
5159  """Create mutually recursive Z3 datatypes using 1 or more Datatype helper objects.
5160 
5161  In the following example we define a Tree-List using two mutually recursive datatypes.
5162 
5163  >>> TreeList = Datatype('TreeList')
5164  >>> Tree = Datatype('Tree')
5165  >>> # Tree has two constructors: leaf and node
5166  >>> Tree.declare('leaf', ('val', IntSort()))
5167  >>> # a node contains a list of trees
5168  >>> Tree.declare('node', ('children', TreeList))
5169  >>> TreeList.declare('nil')
5170  >>> TreeList.declare('cons', ('car', Tree), ('cdr', TreeList))
5171  >>> Tree, TreeList = CreateDatatypes(Tree, TreeList)
5172  >>> Tree.val(Tree.leaf(10))
5173  val(leaf(10))
5174  >>> simplify(Tree.val(Tree.leaf(10)))
5175  10
5176  >>> n1 = Tree.node(TreeList.cons(Tree.leaf(10), TreeList.cons(Tree.leaf(20), TreeList.nil)))
5177  >>> n1
5178  node(cons(leaf(10), cons(leaf(20), nil)))
5179  >>> n2 = Tree.node(TreeList.cons(n1, TreeList.nil))
5180  >>> simplify(n2 == n1)
5181  False
5182  >>> simplify(TreeList.car(Tree.children(n2)) == n1)
5183  True
5184  """
5185  ds = _get_args(ds)
5186  if z3_debug():
5187  _z3_assert(len(ds) > 0, "At least one Datatype must be specified")
5188  _z3_assert(all([isinstance(d, Datatype) for d in ds]), "Arguments must be Datatypes")
5189  _z3_assert(all([d.ctx == ds[0].ctx for d in ds]), "Context mismatch")
5190  _z3_assert(all([d.constructors != [] for d in ds]), "Non-empty Datatypes expected")
5191  ctx = ds[0].ctx
5192  num = len(ds)
5193  names = (Symbol * num)()
5194  out = (Sort * num)()
5195  clists = (ConstructorList * num)()
5196  to_delete = []
5197  for i in range(num):
5198  d = ds[i]
5199  names[i] = to_symbol(d.name, ctx)
5200  num_cs = len(d.constructors)
5201  cs = (Constructor * num_cs)()
5202  for j in range(num_cs):
5203  c = d.constructors[j]
5204  cname = to_symbol(c[0], ctx)
5205  rname = to_symbol(c[1], ctx)
5206  fs = c[2]
5207  num_fs = len(fs)
5208  fnames = (Symbol * num_fs)()
5209  sorts = (Sort * num_fs)()
5210  refs = (ctypes.c_uint * num_fs)()
5211  for k in range(num_fs):
5212  fname = fs[k][0]
5213  ftype = fs[k][1]
5214  fnames[k] = to_symbol(fname, ctx)
5215  if isinstance(ftype, Datatype):
5216  if z3_debug():
5217  _z3_assert(
5218  ds.count(ftype) == 1,
5219  "One and only one occurrence of each datatype is expected",
5220  )
5221  sorts[k] = None
5222  refs[k] = ds.index(ftype)
5223  else:
5224  if z3_debug():
5225  _z3_assert(is_sort(ftype), "Z3 sort expected")
5226  sorts[k] = ftype.ast
5227  refs[k] = 0
5228  cs[j] = Z3_mk_constructor(ctx.ref(), cname, rname, num_fs, fnames, sorts, refs)
5229  to_delete.append(ScopedConstructor(cs[j], ctx))
5230  clists[i] = Z3_mk_constructor_list(ctx.ref(), num_cs, cs)
5231  to_delete.append(ScopedConstructorList(clists[i], ctx))
5232  Z3_mk_datatypes(ctx.ref(), num, names, out, clists)
5233  result = []
5234  # Create a field for every constructor, recognizer and accessor
5235  for i in range(num):
5236  dref = DatatypeSortRef(out[i], ctx)
5237  num_cs = dref.num_constructors()
5238  for j in range(num_cs):
5239  cref = dref.constructor(j)
5240  cref_name = cref.name()
5241  cref_arity = cref.arity()
5242  if cref.arity() == 0:
5243  cref = cref()
5244  setattr(dref, cref_name, cref)
5245  rref = dref.recognizer(j)
5246  setattr(dref, "is_" + cref_name, rref)
5247  for k in range(cref_arity):
5248  aref = dref.accessor(j, k)
5249  setattr(dref, aref.name(), aref)
5250  result.append(dref)
5251  return tuple(result)
5252 
5253 
Z3_mk_constructor
Z3_constructor Z3_API Z3_mk_constructor(Z3_context c, Z3_symbol name, Z3_symbol recognizer, unsigned num_fields, Z3_symbol const field_names[], Z3_sort_opt const sorts[], unsigned sort_refs[])
Create a constructor.
Z3_mk_datatypes
void Z3_API Z3_mk_datatypes(Z3_context c, unsigned num_sorts, Z3_symbol const sort_names[], Z3_sort sorts[], Z3_constructor_list constructor_lists[])
Create mutually recursive datatypes.
Z3_mk_constructor_list
Z3_constructor_list Z3_API Z3_mk_constructor_list(Z3_context c, unsigned num_constructors, Z3_constructor const constructors[])
Create list of constructors.
z3py.CreateDatatypes
def CreateDatatypes(*ds)
Definition: z3py.py:5158

Referenced by Datatype.create().

◆ DatatypeSort()

def z3py.DatatypeSort (   name,
  ctx = None 
) 
Create a reference to a sort that was declared, or will be declared, as a recursive datatype

Definition at line 5358 of file z3py.py.

5358 def DatatypeSort(name, ctx = None):
5359  """Create a reference to a sort that was declared, or will be declared, as a recursive datatype"""
5360  ctx = _get_ctx(ctx)
5361  return DatatypeSortRef(Z3_mk_datatype_sort(ctx.ref(), to_symbol(name, ctx)), ctx)
5362 
Z3_mk_datatype_sort
Z3_sort Z3_API Z3_mk_datatype_sort(Z3_context c, Z3_symbol name)
create a forward reference to a recursive datatype being declared. The forward reference can be used ...
z3py.DatatypeSort
def DatatypeSort(name, ctx=None)
Definition: z3py.py:5358

Referenced by Context.MkDatatypeSort(), and Context.MkDatatypeSorts().

◆ DeclareSort()

def z3py.DeclareSort (   name,
  ctx = None 
) 
Create a new uninterpreted sort named `name`.

If `ctx=None`, then the new sort is declared in the global Z3Py context.

>>> A = DeclareSort('A')
>>> a = Const('a', A)
>>> b = Const('b', A)
>>> a.sort() == A
True
>>> b.sort() == A
True
>>> a == b
a == b

Definition at line 693 of file z3py.py.

693 def DeclareSort(name, ctx=None):
694  """Create a new uninterpreted sort named `name`.
695 
696  If `ctx=None`, then the new sort is declared in the global Z3Py context.
697 
698  >>> A = DeclareSort('A')
699  >>> a = Const('a', A)
700  >>> b = Const('b', A)
701  >>> a.sort() == A
702  True
703  >>> b.sort() == A
704  True
705  >>> a == b
706  a == b
707  """
708  ctx = _get_ctx(ctx)
709  return SortRef(Z3_mk_uninterpreted_sort(ctx.ref(), to_symbol(name, ctx)), ctx)
710 
Z3_mk_uninterpreted_sort
Z3_sort Z3_API Z3_mk_uninterpreted_sort(Z3_context c, Z3_symbol s)
Create a free (uninterpreted) type using the given name (symbol).
z3py.DeclareSort
def DeclareSort(name, ctx=None)
Definition: z3py.py:693

◆ Default()

def z3py.Default (   a) 
 Return a default value for array expression.
>>> b = K(IntSort(), 1)
>>> prove(Default(b) == 1)
proved

Definition at line 4779 of file z3py.py.

4779 def Default(a):
4780  """ Return a default value for array expression.
4781  >>> b = K(IntSort(), 1)
4782  >>> prove(Default(b) == 1)
4783  proved
4784  """
4785  if z3_debug():
4786  _z3_assert(is_array_sort(a), "First argument must be a Z3 array expression")
4787  return a.default()
4788 
4789 
z3py.is_array_sort
def is_array_sort(a)
Definition: z3py.py:4607
z3py.Default
def Default(a)
Definition: z3py.py:4779

◆ describe_probes()

def z3py.describe_probes ( ) 
Display a (tabular) description of all available probes in Z3.

Definition at line 8675 of file z3py.py.

8675 def describe_probes():
8676  """Display a (tabular) description of all available probes in Z3."""
8677  if in_html_mode():
8678  even = True
8679  print('<table border="1" cellpadding="2" cellspacing="0">')
8680  for p in probes():
8681  if even:
8682  print('<tr style="background-color:#CFCFCF">')
8683  even = False
8684  else:
8685  print("<tr>")
8686  even = True
8687  print("<td>%s</td><td>%s</td></tr>" % (p, insert_line_breaks(probe_description(p), 40)))
8688  print("</table>")
8689  else:
8690  for p in probes():
8691  print("%s : %s" % (p, probe_description(p)))
8692 
8693 
z3py.probe_description
def probe_description(name, ctx=None)
Definition: z3py.py:8666
z3py.describe_probes
def describe_probes()
Definition: z3py.py:8675
z3py.probes
def probes(ctx=None)
Definition: z3py.py:8655

◆ describe_tactics()

def z3py.describe_tactics ( ) 
Display a (tabular) description of all available tactics in Z3.

Definition at line 8469 of file z3py.py.

8469 def describe_tactics():
8470  """Display a (tabular) description of all available tactics in Z3."""
8471  if in_html_mode():
8472  even = True
8473  print('<table border="1" cellpadding="2" cellspacing="0">')
8474  for t in tactics():
8475  if even:
8476  print('<tr style="background-color:#CFCFCF">')
8477  even = False
8478  else:
8479  print("<tr>")
8480  even = True
8481  print("<td>%s</td><td>%s</td></tr>" % (t, insert_line_breaks(tactic_description(t), 40)))
8482  print("</table>")
8483  else:
8484  for t in tactics():
8485  print("%s : %s" % (t, tactic_description(t)))
8486 
8487 
z3py.tactics
def tactics(ctx=None)
Definition: z3py.py:8449
z3py.tactic_description
def tactic_description(name, ctx=None)
Definition: z3py.py:8460
z3py.describe_tactics
def describe_tactics()
Definition: z3py.py:8469

◆ deserialize()

def z3py.deserialize (   st) 
inverse function to the serialize method on ExprRef.
It is made available to make it easier for users to serialize expressions back and forth between
strings. Solvers can be serialized using the 'sexpr()' method.

Definition at line 1119 of file z3py.py.

1119 def deserialize(st):
1120  """inverse function to the serialize method on ExprRef.
1121  It is made available to make it easier for users to serialize expressions back and forth between
1122  strings. Solvers can be serialized using the 'sexpr()' method.
1123  """
1124  s = Solver()
1125  s.from_string(st)
1126  if len(s.assertions()) != 1:
1127  raise Z3Exception("single assertion expected")
1128  fml = s.assertions()[0]
1129  if fml.num_args() != 1:
1130  raise Z3Exception("dummy function 'F' expected")
1131  return fml.arg(0)
1132 
z3py.deserialize
def deserialize(st)
Definition: z3py.py:1119

◆ Diff()

def z3py.Diff (   a,
  b,
  ctx = None 
) 
Create the difference regular epression

Definition at line 11293 of file z3py.py.

11293 def Diff(a, b, ctx=None):
11294  """Create the difference regular epression
11295  """
11296  return ReRef(Z3_mk_re_diff(a.ctx_ref(), a.ast, b.ast), a.ctx)
11297 
Z3_mk_re_diff
Z3_ast Z3_API Z3_mk_re_diff(Z3_context c, Z3_ast re1, Z3_ast re2)
Create the difference of regular expressions.
z3py.Diff
def Diff(a, b, ctx=None)
Definition: z3py.py:11293

◆ disable_trace()

def z3py.disable_trace (   msg)

Definition at line 79 of file z3py.py.

79 def disable_trace(msg):
80  Z3_disable_trace(msg)
81 
82 
Z3_disable_trace
void Z3_API Z3_disable_trace(Z3_string tag)
Disable tracing messages tagged as tag when Z3 is compiled in debug mode. It is a NOOP otherwise.
z3py.disable_trace
def disable_trace(msg)
Definition: z3py.py:79

◆ DisjointSum()

def z3py.DisjointSum (   name,
  sorts,
  ctx = None 
) 
Create a named tagged union sort base on a set of underlying sorts
Example:
    >>> sum, ((inject0, extract0), (inject1, extract1)) = DisjointSum("+", [IntSort(), StringSort()])

Definition at line 5375 of file z3py.py.

5375 def DisjointSum(name, sorts, ctx=None):
5376  """Create a named tagged union sort base on a set of underlying sorts
5377  Example:
5378  >>> sum, ((inject0, extract0), (inject1, extract1)) = DisjointSum("+", [IntSort(), StringSort()])
5379  """
5380  sum = Datatype(name, ctx)
5381  for i in range(len(sorts)):
5382  sum.declare("inject%d" % i, ("project%d" % i, sorts[i]))
5383  sum = sum.create()
5384  return sum, [(sum.constructor(i), sum.accessor(i, 0)) for i in range(len(sorts))]
5385 
5386 
z3py.DisjointSum
def DisjointSum(name, sorts, ctx=None)
Definition: z3py.py:5375

◆ Distinct()

def z3py.Distinct ( args) 
Create a Z3 distinct expression.

>>> x = Int('x')
>>> y = Int('y')
>>> Distinct(x, y)
x != y
>>> z = Int('z')
>>> Distinct(x, y, z)
Distinct(x, y, z)
>>> simplify(Distinct(x, y, z))
Distinct(x, y, z)
>>> simplify(Distinct(x, y, z), blast_distinct=True)
And(Not(x == y), Not(x == z), Not(y == z))

Definition at line 1404 of file z3py.py.

1404 def Distinct(*args):
1405  """Create a Z3 distinct expression.
1406 
1407  >>> x = Int('x')
1408  >>> y = Int('y')
1409  >>> Distinct(x, y)
1410  x != y
1411  >>> z = Int('z')
1412  >>> Distinct(x, y, z)
1413  Distinct(x, y, z)
1414  >>> simplify(Distinct(x, y, z))
1415  Distinct(x, y, z)
1416  >>> simplify(Distinct(x, y, z), blast_distinct=True)
1417  And(Not(x == y), Not(x == z), Not(y == z))
1418  """
1419  args = _get_args(args)
1420  ctx = _ctx_from_ast_arg_list(args)
1421  if z3_debug():
1422  _z3_assert(ctx is not None, "At least one of the arguments must be a Z3 expression")
1423  args = _coerce_expr_list(args, ctx)
1424  _args, sz = _to_ast_array(args)
1425  return BoolRef(Z3_mk_distinct(ctx.ref(), sz, _args), ctx)
1426 
1427 
Z3_mk_distinct
Z3_ast Z3_API Z3_mk_distinct(Z3_context c, unsigned num_args, Z3_ast const args[])
Create an AST node representing distinct(args[0], ..., args[num_args-1]).
z3py.Distinct
def Distinct(*args)
Definition: z3py.py:1404

◆ Empty()

def z3py.Empty (   s) 
Create the empty sequence of the given sort
>>> e = Empty(StringSort())
>>> e2 = StringVal("")
>>> print(e.eq(e2))
True
>>> e3 = Empty(SeqSort(IntSort()))
>>> print(e3)
Empty(Seq(Int))
>>> e4 = Empty(ReSort(SeqSort(IntSort())))
>>> print(e4)
Empty(ReSort(Seq(Int)))

Definition at line 10955 of file z3py.py.

10955 def Empty(s):
10956  """Create the empty sequence of the given sort
10957  >>> e = Empty(StringSort())
10958  >>> e2 = StringVal("")
10959  >>> print(e.eq(e2))
10960  True
10961  >>> e3 = Empty(SeqSort(IntSort()))
10962  >>> print(e3)
10963  Empty(Seq(Int))
10964  >>> e4 = Empty(ReSort(SeqSort(IntSort())))
10965  >>> print(e4)
10966  Empty(ReSort(Seq(Int)))
10967  """
10968  if isinstance(s, SeqSortRef):
10969  return SeqRef(Z3_mk_seq_empty(s.ctx_ref(), s.ast), s.ctx)
10970  if isinstance(s, ReSortRef):
10971  return ReRef(Z3_mk_re_empty(s.ctx_ref(), s.ast), s.ctx)
10972  raise Z3Exception("Non-sequence, non-regular expression sort passed to Empty")
10973 
10974 
Z3_mk_seq_empty
Z3_ast Z3_API Z3_mk_seq_empty(Z3_context c, Z3_sort seq)
Create an empty sequence of the sequence sort seq.
Z3_mk_re_empty
Z3_ast Z3_API Z3_mk_re_empty(Z3_context c, Z3_sort re)
Create an empty regular expression of sort re.
z3py.Empty
def Empty(s)
Definition: z3py.py:10955

◆ EmptySet()

def z3py.EmptySet (   s) 
Create the empty set
>>> EmptySet(IntSort())
K(Int, False)

Definition at line 4922 of file z3py.py.

4922 def EmptySet(s):
4923  """Create the empty set
4924  >>> EmptySet(IntSort())
4925  K(Int, False)
4926  """
4927  ctx = s.ctx
4928  return ArrayRef(Z3_mk_empty_set(ctx.ref(), s.ast), ctx)
4929 
4930 
Z3_mk_empty_set
Z3_ast Z3_API Z3_mk_empty_set(Z3_context c, Z3_sort domain)
Create the empty set.
z3py.EmptySet
def EmptySet(s)
Definition: z3py.py:4922

◆ enable_trace()

def z3py.enable_trace (   msg)

Definition at line 75 of file z3py.py.

75 def enable_trace(msg):
76  Z3_enable_trace(msg)
77 
78 
Z3_enable_trace
void Z3_API Z3_enable_trace(Z3_string tag)
Enable tracing messages tagged as tag when Z3 is compiled in debug mode. It is a NOOP otherwise.
z3py.enable_trace
def enable_trace(msg)
Definition: z3py.py:75

◆ ensure_prop_closures()

def z3py.ensure_prop_closures ( )

Definition at line 11408 of file z3py.py.

11408 def ensure_prop_closures():
11409  global _prop_closures
11410  if _prop_closures is None:
11411  _prop_closures = PropClosures()
11412 
11413 
z3py.ensure_prop_closures
def ensure_prop_closures()
Definition: z3py.py:11408

Referenced by UserPropagateBase.__init__().

◆ EnumSort()

def z3py.EnumSort (   name,
  values,
  ctx = None 
) 
Return a new enumeration sort named `name` containing the given values.

The result is a pair (sort, list of constants).
Example:
    >>> Color, (red, green, blue) = EnumSort('Color', ['red', 'green', 'blue'])

Definition at line 5387 of file z3py.py.

5387 def EnumSort(name, values, ctx=None):
5388  """Return a new enumeration sort named `name` containing the given values.
5389 
5390  The result is a pair (sort, list of constants).
5391  Example:
5392  >>> Color, (red, green, blue) = EnumSort('Color', ['red', 'green', 'blue'])
5393  """
5394  if z3_debug():
5395  _z3_assert(isinstance(name, str), "Name must be a string")
5396  _z3_assert(all([isinstance(v, str) for v in values]), "Eumeration sort values must be strings")
5397  _z3_assert(len(values) > 0, "At least one value expected")
5398  ctx = _get_ctx(ctx)
5399  num = len(values)
5400  _val_names = (Symbol * num)()
5401  for i in range(num):
5402  _val_names[i] = to_symbol(values[i])
5403  _values = (FuncDecl * num)()
5404  _testers = (FuncDecl * num)()
5405  name = to_symbol(name)
5406  S = DatatypeSortRef(Z3_mk_enumeration_sort(ctx.ref(), name, num, _val_names, _values, _testers), ctx)
5407  V = []
5408  for i in range(num):
5409  V.append(FuncDeclRef(_values[i], ctx))
5410  V = [a() for a in V]
5411  return S, V
5412 
Z3_mk_enumeration_sort
Z3_sort Z3_API Z3_mk_enumeration_sort(Z3_context c, Z3_symbol name, unsigned n, Z3_symbol const enum_names[], Z3_func_decl enum_consts[], Z3_func_decl enum_testers[])
Create a enumeration sort.
z3py.EnumSort
def EnumSort(name, values, ctx=None)
Definition: z3py.py:5387

Referenced by Context.MkEnumSort().

◆ eq()

def z3py.eq (   a,
  b 
) 
Return `True` if `a` and `b` are structurally identical AST nodes.

>>> x = Int('x')
>>> y = Int('y')
>>> eq(x, y)
False
>>> eq(x + 1, x + 1)
True
>>> eq(x + 1, 1 + x)
False
>>> eq(simplify(x + 1), simplify(1 + x))
True

Definition at line 472 of file z3py.py.

472 def eq(a, b):
473  """Return `True` if `a` and `b` are structurally identical AST nodes.
474 
475  >>> x = Int('x')
476  >>> y = Int('y')
477  >>> eq(x, y)
478  False
479  >>> eq(x + 1, x + 1)
480  True
481  >>> eq(x + 1, 1 + x)
482  False
483  >>> eq(simplify(x + 1), simplify(1 + x))
484  True
485  """
486  if z3_debug():
487  _z3_assert(is_ast(a) and is_ast(b), "Z3 ASTs expected")
488  return a.eq(b)
489 
490 
z3py.is_ast
def is_ast(a)
Definition: z3py.py:451
z3py.eq
def eq(a, b)
Definition: z3py.py:472

Referenced by substitute().

◆ Exists()

def z3py.Exists (   vs,
  body,
  weight = 1,
  qid = "",
  skid = "",
  patterns = [],
  no_patterns = [] 
) 
Create a Z3 exists formula.

The parameters `weight`, `qif`, `skid`, `patterns` and `no_patterns` are optional annotations.


>>> f = Function('f', IntSort(), IntSort(), IntSort())
>>> x = Int('x')
>>> y = Int('y')
>>> q = Exists([x, y], f(x, y) >= x, skid="foo")
>>> q
Exists([x, y], f(x, y) >= x)
>>> is_quantifier(q)
True
>>> r = Tactic('nnf')(q).as_expr()
>>> is_quantifier(r)
False

Definition at line 2240 of file z3py.py.

2240 def Exists(vs, body, weight=1, qid="", skid="", patterns=[], no_patterns=[]):
2241  """Create a Z3 exists formula.
2242 
2243  The parameters `weight`, `qif`, `skid`, `patterns` and `no_patterns` are optional annotations.
2244 
2245 
2246  >>> f = Function('f', IntSort(), IntSort(), IntSort())
2247  >>> x = Int('x')
2248  >>> y = Int('y')
2249  >>> q = Exists([x, y], f(x, y) >= x, skid="foo")
2250  >>> q
2251  Exists([x, y], f(x, y) >= x)
2252  >>> is_quantifier(q)
2253  True
2254  >>> r = Tactic('nnf')(q).as_expr()
2255  >>> is_quantifier(r)
2256  False
2257  """
2258  return _mk_quantifier(False, vs, body, weight, qid, skid, patterns, no_patterns)
2259 
2260 
z3py.Exists
def Exists(vs, body, weight=1, qid="", skid="", patterns=[], no_patterns=[])
Definition: z3py.py:2240

Referenced by Fixedpoint.abstract().

◆ Ext()

def z3py.Ext (   a,
  b 
) 
Return extensionality index for one-dimensional arrays.
>> a, b = Consts('a b', SetSort(IntSort()))
>> Ext(a, b)
Ext(a, b)

Definition at line 4868 of file z3py.py.

4868 def Ext(a, b):
4869  """Return extensionality index for one-dimensional arrays.
4870  >> a, b = Consts('a b', SetSort(IntSort()))
4871  >> Ext(a, b)
4872  Ext(a, b)
4873  """
4874  ctx = a.ctx
4875  if z3_debug():
4876  _z3_assert(is_array_sort(a) and (is_array(b) or b.is_lambda()), "arguments must be arrays")
4877  return _to_expr_ref(Z3_mk_array_ext(ctx.ref(), a.as_ast(), b.as_ast()), ctx)
4878 
4879 
Z3_mk_array_ext
Z3_ast Z3_API Z3_mk_array_ext(Z3_context c, Z3_ast arg1, Z3_ast arg2)
Create array extensionality index given two arrays with the same sort. The meaning is given by the ax...
z3py.is_array
def is_array(a)
Definition: z3py.py:4611
z3py.Ext
def Ext(a, b)
Definition: z3py.py:4868

◆ Extract()

def z3py.Extract (   high,
  low,
  a 
) 
Create a Z3 bit-vector extraction expression.
Extract is overloaded to also work on sequence extraction.
The functions SubString and SubSeq are redirected to Extract.
For this case, the arguments are reinterpreted as:
    high - is a sequence (string)
    low  - is an offset
    a    - is the length to be extracted

>>> x = BitVec('x', 8)
>>> Extract(6, 2, x)
Extract(6, 2, x)
>>> Extract(6, 2, x).sort()
BitVec(5)
>>> simplify(Extract(StringVal("abcd"),2,1))
"c"

Definition at line 4128 of file z3py.py.

4128 def Extract(high, low, a):
4129  """Create a Z3 bit-vector extraction expression.
4130  Extract is overloaded to also work on sequence extraction.
4131  The functions SubString and SubSeq are redirected to Extract.
4132  For this case, the arguments are reinterpreted as:
4133  high - is a sequence (string)
4134  low - is an offset
4135  a - is the length to be extracted
4136 
4137  >>> x = BitVec('x', 8)
4138  >>> Extract(6, 2, x)
4139  Extract(6, 2, x)
4140  >>> Extract(6, 2, x).sort()
4141  BitVec(5)
4142  >>> simplify(Extract(StringVal("abcd"),2,1))
4143  "c"
4144  """
4145  if isinstance(high, str):
4146  high = StringVal(high)
4147  if is_seq(high):
4148  s = high
4149  offset, length = _coerce_exprs(low, a, s.ctx)
4150  return SeqRef(Z3_mk_seq_extract(s.ctx_ref(), s.as_ast(), offset.as_ast(), length.as_ast()), s.ctx)
4151  if z3_debug():
4152  _z3_assert(low <= high, "First argument must be greater than or equal to second argument")
4153  _z3_assert(_is_int(high) and high >= 0 and _is_int(low) and low >= 0,
4154  "First and second arguments must be non negative integers")
4155  _z3_assert(is_bv(a), "Third argument must be a Z3 bit-vector expression")
4156  return BitVecRef(Z3_mk_extract(a.ctx_ref(), high, low, a.as_ast()), a.ctx)
4157 
4158 
Z3_mk_extract
Z3_ast Z3_API Z3_mk_extract(Z3_context c, unsigned high, unsigned low, Z3_ast t1)
Extract the bits high down to low from a bit-vector of size m to yield a new bit-vector of size n,...
Z3_mk_seq_extract
Z3_ast Z3_API Z3_mk_seq_extract(Z3_context c, Z3_ast s, Z3_ast offset, Z3_ast length)
Extract subsequence starting at offset of length.
z3py.Extract
def Extract(high, low, a)
Definition: z3py.py:4128
z3py.StringVal
def StringVal(s, ctx=None)
Definition: z3py.py:10921

Referenced by SubSeq(), and SubString().

◆ FailIf()

def z3py.FailIf (   p,
  ctx = None 
) 
Return a tactic that fails if the probe `p` evaluates to true.
Otherwise, it returns the input goal unmodified.

In the following example, the tactic applies 'simplify' if and only if there are
more than 2 constraints in the goal.

>>> t = OrElse(FailIf(Probe('size') > 2), Tactic('simplify'))
>>> x, y = Ints('x y')
>>> g = Goal()
>>> g.add(x > 0)
>>> g.add(y > 0)
>>> t(g)
[[x > 0, y > 0]]
>>> g.add(x == y + 1)
>>> t(g)
[[Not(x <= 0), Not(y <= 0), x == 1 + y]]

Definition at line 8712 of file z3py.py.

8712 def FailIf(p, ctx=None):
8713  """Return a tactic that fails if the probe `p` evaluates to true.
8714  Otherwise, it returns the input goal unmodified.
8715 
8716  In the following example, the tactic applies 'simplify' if and only if there are
8717  more than 2 constraints in the goal.
8718 
8719  >>> t = OrElse(FailIf(Probe('size') > 2), Tactic('simplify'))
8720  >>> x, y = Ints('x y')
8721  >>> g = Goal()
8722  >>> g.add(x > 0)
8723  >>> g.add(y > 0)
8724  >>> t(g)
8725  [[x > 0, y > 0]]
8726  >>> g.add(x == y + 1)
8727  >>> t(g)
8728  [[Not(x <= 0), Not(y <= 0), x == 1 + y]]
8729  """
8730  p = _to_probe(p, ctx)
8731  return Tactic(Z3_tactic_fail_if(p.ctx.ref(), p.probe), p.ctx)
8732 
8733 
Z3_tactic_fail_if
Z3_tactic Z3_API Z3_tactic_fail_if(Z3_context c, Z3_probe p)
Return a tactic that fails if the probe p evaluates to false.
z3py.FailIf
def FailIf(p, ctx=None)
Definition: z3py.py:8712

◆ FiniteDomainSort()

def z3py.FiniteDomainSort (   name,
  sz,
  ctx = None 
) 
Create a named finite domain sort of a given size sz

Definition at line 7716 of file z3py.py.

7716 def FiniteDomainSort(name, sz, ctx=None):
7717  """Create a named finite domain sort of a given size sz"""
7718  if not isinstance(name, Symbol):
7719  name = to_symbol(name)
7720  ctx = _get_ctx(ctx)
7721  return FiniteDomainSortRef(Z3_mk_finite_domain_sort(ctx.ref(), name, sz), ctx)
7722 
7723 
Z3_mk_finite_domain_sort
Z3_sort Z3_API Z3_mk_finite_domain_sort(Z3_context c, Z3_symbol name, uint64_t size)
Create a named finite domain sort.
z3py.FiniteDomainSort
def FiniteDomainSort(name, sz, ctx=None)
Definition: z3py.py:7716

Referenced by Context.MkFiniteDomainSort().

◆ FiniteDomainVal()

def z3py.FiniteDomainVal (   val,
  sort,
  ctx = None 
) 
Return a Z3 finite-domain value. If `ctx=None`, then the global context is used.

>>> s = FiniteDomainSort('S', 256)
>>> FiniteDomainVal(255, s)
255
>>> FiniteDomainVal('100', s)
100

Definition at line 7786 of file z3py.py.

7786 def FiniteDomainVal(val, sort, ctx=None):
7787  """Return a Z3 finite-domain value. If `ctx=None`, then the global context is used.
7788 
7789  >>> s = FiniteDomainSort('S', 256)
7790  >>> FiniteDomainVal(255, s)
7791  255
7792  >>> FiniteDomainVal('100', s)
7793  100
7794  """
7795  if z3_debug():
7796  _z3_assert(is_finite_domain_sort(sort), "Expected finite-domain sort")
7797  ctx = sort.ctx
7798  return FiniteDomainNumRef(Z3_mk_numeral(ctx.ref(), _to_int_str(val), sort.ast), ctx)
7799 
7800 
z3py.FiniteDomainVal
def FiniteDomainVal(val, sort, ctx=None)
Definition: z3py.py:7786
z3py.is_finite_domain_sort
def is_finite_domain_sort(s)
Definition: z3py.py:7724

◆ Float128()

def z3py.Float128 (   ctx = None) 
Floating-point 128-bit (quadruple) sort.

Definition at line 9440 of file z3py.py.

9440 def Float128(ctx=None):
9441  """Floating-point 128-bit (quadruple) sort."""
9442  ctx = _get_ctx(ctx)
9443  return FPSortRef(Z3_mk_fpa_sort_128(ctx.ref()), ctx)
9444 
9445 
Z3_mk_fpa_sort_128
Z3_sort Z3_API Z3_mk_fpa_sort_128(Z3_context c)
Create the quadruple-precision (128-bit) FloatingPoint sort.
z3py.Float128
def Float128(ctx=None)
Definition: z3py.py:9440

◆ Float16()

def z3py.Float16 (   ctx = None) 
Floating-point 16-bit (half) sort.

Definition at line 9404 of file z3py.py.

9404 def Float16(ctx=None):
9405  """Floating-point 16-bit (half) sort."""
9406  ctx = _get_ctx(ctx)
9407  return FPSortRef(Z3_mk_fpa_sort_16(ctx.ref()), ctx)
9408 
9409 
Z3_mk_fpa_sort_16
Z3_sort Z3_API Z3_mk_fpa_sort_16(Z3_context c)
Create the half-precision (16-bit) FloatingPoint sort.
z3py.Float16
def Float16(ctx=None)
Definition: z3py.py:9404

◆ Float32()

def z3py.Float32 (   ctx = None) 
Floating-point 32-bit (single) sort.

Definition at line 9416 of file z3py.py.

9416 def Float32(ctx=None):
9417  """Floating-point 32-bit (single) sort."""
9418  ctx = _get_ctx(ctx)
9419  return FPSortRef(Z3_mk_fpa_sort_32(ctx.ref()), ctx)
9420 
9421 
Z3_mk_fpa_sort_32
Z3_sort Z3_API Z3_mk_fpa_sort_32(Z3_context c)
Create the single-precision (32-bit) FloatingPoint sort.
z3py.Float32
def Float32(ctx=None)
Definition: z3py.py:9416

◆ Float64()

def z3py.Float64 (   ctx = None) 
Floating-point 64-bit (double) sort.

Definition at line 9428 of file z3py.py.

9428 def Float64(ctx=None):
9429  """Floating-point 64-bit (double) sort."""
9430  ctx = _get_ctx(ctx)
9431  return FPSortRef(Z3_mk_fpa_sort_64(ctx.ref()), ctx)
9432 
9433 
Z3_mk_fpa_sort_64
Z3_sort Z3_API Z3_mk_fpa_sort_64(Z3_context c)
Create the double-precision (64-bit) FloatingPoint sort.
z3py.Float64
def Float64(ctx=None)
Definition: z3py.py:9428

◆ FloatDouble()

def z3py.FloatDouble (   ctx = None) 
Floating-point 64-bit (double) sort.

Definition at line 9434 of file z3py.py.

9434 def FloatDouble(ctx=None):
9435  """Floating-point 64-bit (double) sort."""
9436  ctx = _get_ctx(ctx)
9437  return FPSortRef(Z3_mk_fpa_sort_double(ctx.ref()), ctx)
9438 
9439 
Z3_mk_fpa_sort_double
Z3_sort Z3_API Z3_mk_fpa_sort_double(Z3_context c)
Create the double-precision (64-bit) FloatingPoint sort.
z3py.FloatDouble
def FloatDouble(ctx=None)
Definition: z3py.py:9434

◆ FloatHalf()

def z3py.FloatHalf (   ctx = None) 
Floating-point 16-bit (half) sort.

Definition at line 9410 of file z3py.py.

9410 def FloatHalf(ctx=None):
9411  """Floating-point 16-bit (half) sort."""
9412  ctx = _get_ctx(ctx)
9413  return FPSortRef(Z3_mk_fpa_sort_half(ctx.ref()), ctx)
9414 
9415 
Z3_mk_fpa_sort_half
Z3_sort Z3_API Z3_mk_fpa_sort_half(Z3_context c)
Create the half-precision (16-bit) FloatingPoint sort.
z3py.FloatHalf
def FloatHalf(ctx=None)
Definition: z3py.py:9410

◆ FloatQuadruple()

def z3py.FloatQuadruple (   ctx = None) 
Floating-point 128-bit (quadruple) sort.

Definition at line 9446 of file z3py.py.

9446 def FloatQuadruple(ctx=None):
9447  """Floating-point 128-bit (quadruple) sort."""
9448  ctx = _get_ctx(ctx)
9449  return FPSortRef(Z3_mk_fpa_sort_quadruple(ctx.ref()), ctx)
9450 
9451 
Z3_mk_fpa_sort_quadruple
Z3_sort Z3_API Z3_mk_fpa_sort_quadruple(Z3_context c)
Create the quadruple-precision (128-bit) FloatingPoint sort.
z3py.FloatQuadruple
def FloatQuadruple(ctx=None)
Definition: z3py.py:9446

◆ FloatSingle()

def z3py.FloatSingle (   ctx = None) 
Floating-point 32-bit (single) sort.

Definition at line 9422 of file z3py.py.

9422 def FloatSingle(ctx=None):
9423  """Floating-point 32-bit (single) sort."""
9424  ctx = _get_ctx(ctx)
9425  return FPSortRef(Z3_mk_fpa_sort_single(ctx.ref()), ctx)
9426 
9427 
Z3_mk_fpa_sort_single
Z3_sort Z3_API Z3_mk_fpa_sort_single(Z3_context c)
Create the single-precision (32-bit) FloatingPoint sort.
z3py.FloatSingle
def FloatSingle(ctx=None)
Definition: z3py.py:9422

◆ ForAll()

def z3py.ForAll (   vs,
  body,
  weight = 1,
  qid = "",
  skid = "",
  patterns = [],
  no_patterns = [] 
) 
Create a Z3 forall formula.

The parameters `weight`, `qid`, `skid`, `patterns` and `no_patterns` are optional annotations.

>>> f = Function('f', IntSort(), IntSort(), IntSort())
>>> x = Int('x')
>>> y = Int('y')
>>> ForAll([x, y], f(x, y) >= x)
ForAll([x, y], f(x, y) >= x)
>>> ForAll([x, y], f(x, y) >= x, patterns=[ f(x, y) ])
ForAll([x, y], f(x, y) >= x)
>>> ForAll([x, y], f(x, y) >= x, weight=10)
ForAll([x, y], f(x, y) >= x)

Definition at line 2222 of file z3py.py.

2222 def ForAll(vs, body, weight=1, qid="", skid="", patterns=[], no_patterns=[]):
2223  """Create a Z3 forall formula.
2224 
2225  The parameters `weight`, `qid`, `skid`, `patterns` and `no_patterns` are optional annotations.
2226 
2227  >>> f = Function('f', IntSort(), IntSort(), IntSort())
2228  >>> x = Int('x')
2229  >>> y = Int('y')
2230  >>> ForAll([x, y], f(x, y) >= x)
2231  ForAll([x, y], f(x, y) >= x)
2232  >>> ForAll([x, y], f(x, y) >= x, patterns=[ f(x, y) ])
2233  ForAll([x, y], f(x, y) >= x)
2234  >>> ForAll([x, y], f(x, y) >= x, weight=10)
2235  ForAll([x, y], f(x, y) >= x)
2236  """
2237  return _mk_quantifier(True, vs, body, weight, qid, skid, patterns, no_patterns)
2238 
2239 
z3py.ForAll
def ForAll(vs, body, weight=1, qid="", skid="", patterns=[], no_patterns=[])
Definition: z3py.py:2222

Referenced by Fixedpoint.abstract().

◆ FP()

def z3py.FP (   name,
  fpsort,
  ctx = None 
) 
Return a floating-point constant named `name`.
`fpsort` is the floating-point sort.
If `ctx=None`, then the global context is used.

>>> x  = FP('x', FPSort(8, 24))
>>> is_fp(x)
True
>>> x.ebits()
8
>>> x.sort()
FPSort(8, 24)
>>> word = FPSort(8, 24)
>>> x2 = FP('x', word)
>>> eq(x, x2)
True

Definition at line 10072 of file z3py.py.

10072 def FP(name, fpsort, ctx=None):
10073  """Return a floating-point constant named `name`.
10074  `fpsort` is the floating-point sort.
10075  If `ctx=None`, then the global context is used.
10076 
10077  >>> x = FP('x', FPSort(8, 24))
10078  >>> is_fp(x)
10079  True
10080  >>> x.ebits()
10081  8
10082  >>> x.sort()
10083  FPSort(8, 24)
10084  >>> word = FPSort(8, 24)
10085  >>> x2 = FP('x', word)
10086  >>> eq(x, x2)
10087  True
10088  """
10089  if isinstance(fpsort, FPSortRef) and ctx is None:
10090  ctx = fpsort.ctx
10091  else:
10092  ctx = _get_ctx(ctx)
10093  return FPRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), fpsort.ast), ctx)
10094 
10095 
z3py.FP
def FP(name, fpsort, ctx=None)
Definition: z3py.py:10072

Referenced by FPs().

◆ fpAbs()

def z3py.fpAbs (   a,
  ctx = None 
) 
Create a Z3 floating-point absolute value expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FPVal(1.0, s)
>>> fpAbs(x)
fpAbs(1)
>>> y = FPVal(-20.0, s)
>>> y
-1.25*(2**4)
>>> fpAbs(y)
fpAbs(-1.25*(2**4))
>>> fpAbs(-1.25*(2**4))
fpAbs(-1.25*(2**4))
>>> fpAbs(x).sort()
FPSort(8, 24)

Definition at line 10115 of file z3py.py.

10115 def fpAbs(a, ctx=None):
10116  """Create a Z3 floating-point absolute value expression.
10117 
10118  >>> s = FPSort(8, 24)
10119  >>> rm = RNE()
10120  >>> x = FPVal(1.0, s)
10121  >>> fpAbs(x)
10122  fpAbs(1)
10123  >>> y = FPVal(-20.0, s)
10124  >>> y
10125  -1.25*(2**4)
10126  >>> fpAbs(y)
10127  fpAbs(-1.25*(2**4))
10128  >>> fpAbs(-1.25*(2**4))
10129  fpAbs(-1.25*(2**4))
10130  >>> fpAbs(x).sort()
10131  FPSort(8, 24)
10132  """
10133  ctx = _get_ctx(ctx)
10134  [a] = _coerce_fp_expr_list([a], ctx)
10135  return FPRef(Z3_mk_fpa_abs(ctx.ref(), a.as_ast()), ctx)
10136 
10137 
Z3_mk_fpa_abs
Z3_ast Z3_API Z3_mk_fpa_abs(Z3_context c, Z3_ast t)
Floating-point absolute value.
z3py.fpAbs
def fpAbs(a, ctx=None)
Definition: z3py.py:10115

◆ fpAdd()

def z3py.fpAdd (   rm,
  a,
  b,
  ctx = None 
) 
Create a Z3 floating-point addition expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpAdd(rm, x, y)
x + y
>>> fpAdd(RTZ(), x, y) # default rounding mode is RTZ
fpAdd(RTZ(), x, y)
>>> fpAdd(rm, x, y).sort()
FPSort(8, 24)

Definition at line 10206 of file z3py.py.

10206 def fpAdd(rm, a, b, ctx=None):
10207  """Create a Z3 floating-point addition expression.
10208 
10209  >>> s = FPSort(8, 24)
10210  >>> rm = RNE()
10211  >>> x = FP('x', s)
10212  >>> y = FP('y', s)
10213  >>> fpAdd(rm, x, y)
10214  x + y
10215  >>> fpAdd(RTZ(), x, y) # default rounding mode is RTZ
10216  fpAdd(RTZ(), x, y)
10217  >>> fpAdd(rm, x, y).sort()
10218  FPSort(8, 24)
10219  """
10220  return _mk_fp_bin(Z3_mk_fpa_add, rm, a, b, ctx)
10221 
10222 
z3py.fpAdd
def fpAdd(rm, a, b, ctx=None)
Definition: z3py.py:10206

Referenced by FPRef.__add__(), and FPRef.__radd__().

◆ fpBVToFP()

def z3py.fpBVToFP (   v,
  sort,
  ctx = None 
) 
Create a Z3 floating-point conversion expression that represents the
conversion from a bit-vector term to a floating-point term.

>>> x_bv = BitVecVal(0x3F800000, 32)
>>> x_fp = fpBVToFP(x_bv, Float32())
>>> x_fp
fpToFP(1065353216)
>>> simplify(x_fp)
1

Definition at line 10528 of file z3py.py.

10528 def fpBVToFP(v, sort, ctx=None):
10529  """Create a Z3 floating-point conversion expression that represents the
10530  conversion from a bit-vector term to a floating-point term.
10531 
10532  >>> x_bv = BitVecVal(0x3F800000, 32)
10533  >>> x_fp = fpBVToFP(x_bv, Float32())
10534  >>> x_fp
10535  fpToFP(1065353216)
10536  >>> simplify(x_fp)
10537  1
10538  """
10539  _z3_assert(is_bv(v), "First argument must be a Z3 bit-vector expression")
10540  _z3_assert(is_fp_sort(sort), "Second argument must be a Z3 floating-point sort.")
10541  ctx = _get_ctx(ctx)
10542  return FPRef(Z3_mk_fpa_to_fp_bv(ctx.ref(), v.ast, sort.ast), ctx)
10543 
10544 
Z3_mk_fpa_to_fp_bv
Z3_ast Z3_API Z3_mk_fpa_to_fp_bv(Z3_context c, Z3_ast bv, Z3_sort s)
Conversion of a single IEEE 754-2008 bit-vector into a floating-point number.
z3py.is_fp_sort
def is_fp_sort(s)
Definition: z3py.py:9456
z3py.fpBVToFP
def fpBVToFP(v, sort, ctx=None)
Definition: z3py.py:10528

◆ fpDiv()

def z3py.fpDiv (   rm,
  a,
  b,
  ctx = None 
) 
Create a Z3 floating-point division expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpDiv(rm, x, y)
x / y
>>> fpDiv(rm, x, y).sort()
FPSort(8, 24)

Definition at line 10253 of file z3py.py.

10253 def fpDiv(rm, a, b, ctx=None):
10254  """Create a Z3 floating-point division expression.
10255 
10256  >>> s = FPSort(8, 24)
10257  >>> rm = RNE()
10258  >>> x = FP('x', s)
10259  >>> y = FP('y', s)
10260  >>> fpDiv(rm, x, y)
10261  x / y
10262  >>> fpDiv(rm, x, y).sort()
10263  FPSort(8, 24)
10264  """
10265  return _mk_fp_bin(Z3_mk_fpa_div, rm, a, b, ctx)
10266 
10267 
z3py.fpDiv
def fpDiv(rm, a, b, ctx=None)
Definition: z3py.py:10253

Referenced by FPRef.__div__(), and FPRef.__rdiv__().

◆ fpEQ()

def z3py.fpEQ (   a,
  b,
  ctx = None 
) 
Create the Z3 floating-point expression `fpEQ(other, self)`.

>>> x, y = FPs('x y', FPSort(8, 24))
>>> fpEQ(x, y)
fpEQ(x, y)
>>> fpEQ(x, y).sexpr()
'(fp.eq x y)'

Definition at line 10436 of file z3py.py.

10436 def fpEQ(a, b, ctx=None):
10437  """Create the Z3 floating-point expression `fpEQ(other, self)`.
10438 
10439  >>> x, y = FPs('x y', FPSort(8, 24))
10440  >>> fpEQ(x, y)
10441  fpEQ(x, y)
10442  >>> fpEQ(x, y).sexpr()
10443  '(fp.eq x y)'
10444  """
10445  return _mk_fp_bin_pred(Z3_mk_fpa_eq, a, b, ctx)
10446 
10447 
z3py.fpEQ
def fpEQ(a, b, ctx=None)
Definition: z3py.py:10436

Referenced by fpNEQ().

◆ fpFMA()

def z3py.fpFMA (   rm,
  a,
  b,
  c,
  ctx = None 
) 
Create a Z3 floating-point fused multiply-add expression.

Definition at line 10312 of file z3py.py.

10312 def fpFMA(rm, a, b, c, ctx=None):
10313  """Create a Z3 floating-point fused multiply-add expression.
10314  """
10315  return _mk_fp_tern(Z3_mk_fpa_fma, rm, a, b, c, ctx)
10316 
10317 
z3py.fpFMA
def fpFMA(rm, a, b, c, ctx=None)
Definition: z3py.py:10312

◆ fpFP()

def z3py.fpFP (   sgn,
  exp,
  sig,
  ctx = None 
) 
Create the Z3 floating-point value `fpFP(sgn, sig, exp)` from the three bit-vectors sgn, sig, and exp.

>>> s = FPSort(8, 24)
>>> x = fpFP(BitVecVal(1, 1), BitVecVal(2**7-1, 8), BitVecVal(2**22, 23))
>>> print(x)
fpFP(1, 127, 4194304)
>>> xv = FPVal(-1.5, s)
>>> print(xv)
-1.5
>>> slvr = Solver()
>>> slvr.add(fpEQ(x, xv))
>>> slvr.check()
sat
>>> xv = FPVal(+1.5, s)
>>> print(xv)
1.5
>>> slvr = Solver()
>>> slvr.add(fpEQ(x, xv))
>>> slvr.check()
unsat

Definition at line 10460 of file z3py.py.

10460 def fpFP(sgn, exp, sig, ctx=None):
10461  """Create the Z3 floating-point value `fpFP(sgn, sig, exp)` from the three bit-vectors sgn, sig, and exp.
10462 
10463  >>> s = FPSort(8, 24)
10464  >>> x = fpFP(BitVecVal(1, 1), BitVecVal(2**7-1, 8), BitVecVal(2**22, 23))
10465  >>> print(x)
10466  fpFP(1, 127, 4194304)
10467  >>> xv = FPVal(-1.5, s)
10468  >>> print(xv)
10469  -1.5
10470  >>> slvr = Solver()
10471  >>> slvr.add(fpEQ(x, xv))
10472  >>> slvr.check()
10473  sat
10474  >>> xv = FPVal(+1.5, s)
10475  >>> print(xv)
10476  1.5
10477  >>> slvr = Solver()
10478  >>> slvr.add(fpEQ(x, xv))
10479  >>> slvr.check()
10480  unsat
10481  """
10482  _z3_assert(is_bv(sgn) and is_bv(exp) and is_bv(sig), "sort mismatch")
10483  _z3_assert(sgn.sort().size() == 1, "sort mismatch")
10484  ctx = _get_ctx(ctx)
10485  _z3_assert(ctx == sgn.ctx == exp.ctx == sig.ctx, "context mismatch")
10486  return FPRef(Z3_mk_fpa_fp(ctx.ref(), sgn.ast, exp.ast, sig.ast), ctx)
10487 
10488 
Z3_mk_fpa_fp
Z3_ast Z3_API Z3_mk_fpa_fp(Z3_context c, Z3_ast sgn, Z3_ast exp, Z3_ast sig)
Create an expression of FloatingPoint sort from three bit-vector expressions.
z3py.fpFP
def fpFP(sgn, exp, sig, ctx=None)
Definition: z3py.py:10460

◆ fpFPToFP()

def z3py.fpFPToFP (   rm,
  v,
  sort,
  ctx = None 
) 
Create a Z3 floating-point conversion expression that represents the
conversion from a floating-point term to a floating-point term of different precision.

>>> x_sgl = FPVal(1.0, Float32())
>>> x_dbl = fpFPToFP(RNE(), x_sgl, Float64())
>>> x_dbl
fpToFP(RNE(), 1)
>>> simplify(x_dbl)
1
>>> x_dbl.sort()
FPSort(11, 53)

Definition at line 10545 of file z3py.py.

10545 def fpFPToFP(rm, v, sort, ctx=None):
10546  """Create a Z3 floating-point conversion expression that represents the
10547  conversion from a floating-point term to a floating-point term of different precision.
10548 
10549  >>> x_sgl = FPVal(1.0, Float32())
10550  >>> x_dbl = fpFPToFP(RNE(), x_sgl, Float64())
10551  >>> x_dbl
10552  fpToFP(RNE(), 1)
10553  >>> simplify(x_dbl)
10554  1
10555  >>> x_dbl.sort()
10556  FPSort(11, 53)
10557  """
10558  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression.")
10559  _z3_assert(is_fp(v), "Second argument must be a Z3 floating-point expression.")
10560  _z3_assert(is_fp_sort(sort), "Third argument must be a Z3 floating-point sort.")
10561  ctx = _get_ctx(ctx)
10562  return FPRef(Z3_mk_fpa_to_fp_float(ctx.ref(), rm.ast, v.ast, sort.ast), ctx)
10563 
10564 
Z3_mk_fpa_to_fp_float
Z3_ast Z3_API Z3_mk_fpa_to_fp_float(Z3_context c, Z3_ast rm, Z3_ast t, Z3_sort s)
Conversion of a FloatingPoint term into another term of different FloatingPoint sort.
z3py.fpFPToFP
def fpFPToFP(rm, v, sort, ctx=None)
Definition: z3py.py:10545
z3py.is_fprm
def is_fprm(a)
Definition: z3py.py:9716
z3py.is_fp
def is_fp(a)
Definition: z3py.py:9872

◆ fpGEQ()

def z3py.fpGEQ (   a,
  b,
  ctx = None 
) 
Create the Z3 floating-point expression `other >= self`.

>>> x, y = FPs('x y', FPSort(8, 24))
>>> fpGEQ(x, y)
x >= y
>>> (x >= y).sexpr()
'(fp.geq x y)'

Definition at line 10424 of file z3py.py.

10424 def fpGEQ(a, b, ctx=None):
10425  """Create the Z3 floating-point expression `other >= self`.
10426 
10427  >>> x, y = FPs('x y', FPSort(8, 24))
10428  >>> fpGEQ(x, y)
10429  x >= y
10430  >>> (x >= y).sexpr()
10431  '(fp.geq x y)'
10432  """
10433  return _mk_fp_bin_pred(Z3_mk_fpa_geq, a, b, ctx)
10434 
10435 
z3py.fpGEQ
def fpGEQ(a, b, ctx=None)
Definition: z3py.py:10424

Referenced by FPRef.__ge__().

◆ fpGT()

def z3py.fpGT (   a,
  b,
  ctx = None 
) 
Create the Z3 floating-point expression `other > self`.

>>> x, y = FPs('x y', FPSort(8, 24))
>>> fpGT(x, y)
x > y
>>> (x > y).sexpr()
'(fp.gt x y)'

Definition at line 10412 of file z3py.py.

10412 def fpGT(a, b, ctx=None):
10413  """Create the Z3 floating-point expression `other > self`.
10414 
10415  >>> x, y = FPs('x y', FPSort(8, 24))
10416  >>> fpGT(x, y)
10417  x > y
10418  >>> (x > y).sexpr()
10419  '(fp.gt x y)'
10420  """
10421  return _mk_fp_bin_pred(Z3_mk_fpa_gt, a, b, ctx)
10422 
10423 
z3py.fpGT
def fpGT(a, b, ctx=None)
Definition: z3py.py:10412

Referenced by FPRef.__gt__().

◆ fpInfinity()

def z3py.fpInfinity (   s,
  negative 
) 
Create a Z3 floating-point +oo or -oo term.

Definition at line 10000 of file z3py.py.

10000 def fpInfinity(s, negative):
10001  """Create a Z3 floating-point +oo or -oo term."""
10002  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
10003  _z3_assert(isinstance(negative, bool), "expected Boolean flag")
10004  return FPNumRef(Z3_mk_fpa_inf(s.ctx_ref(), s.ast, negative), s.ctx)
10005 
10006 
Z3_mk_fpa_inf
Z3_ast Z3_API Z3_mk_fpa_inf(Z3_context c, Z3_sort s, bool negative)
Create a floating-point infinity of sort s.
z3py.fpInfinity
def fpInfinity(s, negative)
Definition: z3py.py:10000

◆ fpIsInf()

def z3py.fpIsInf (   a,
  ctx = None 
) 
Create a Z3 floating-point isInfinite expression.

>>> s = FPSort(8, 24)
>>> x = FP('x', s)
>>> fpIsInf(x)
fpIsInf(x)

Definition at line 10342 of file z3py.py.

10342 def fpIsInf(a, ctx=None):
10343  """Create a Z3 floating-point isInfinite expression.
10344 
10345  >>> s = FPSort(8, 24)
10346  >>> x = FP('x', s)
10347  >>> fpIsInf(x)
10348  fpIsInf(x)
10349  """
10350  return _mk_fp_unary_pred(Z3_mk_fpa_is_infinite, a, ctx)
10351 
10352 
z3py.fpIsInf
def fpIsInf(a, ctx=None)
Definition: z3py.py:10342

◆ fpIsNaN()

def z3py.fpIsNaN (   a,
  ctx = None 
) 
Create a Z3 floating-point isNaN expression.

>>> s = FPSort(8, 24)
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpIsNaN(x)
fpIsNaN(x)

Definition at line 10330 of file z3py.py.

10330 def fpIsNaN(a, ctx=None):
10331  """Create a Z3 floating-point isNaN expression.
10332 
10333  >>> s = FPSort(8, 24)
10334  >>> x = FP('x', s)
10335  >>> y = FP('y', s)
10336  >>> fpIsNaN(x)
10337  fpIsNaN(x)
10338  """
10339  return _mk_fp_unary_pred(Z3_mk_fpa_is_nan, a, ctx)
10340 
10341 
z3py.fpIsNaN
def fpIsNaN(a, ctx=None)
Definition: z3py.py:10330

◆ fpIsNegative()

def z3py.fpIsNegative (   a,
  ctx = None 
) 
Create a Z3 floating-point isNegative expression.

Definition at line 10371 of file z3py.py.

10371 def fpIsNegative(a, ctx=None):
10372  """Create a Z3 floating-point isNegative expression.
10373  """
10374  return _mk_fp_unary_pred(Z3_mk_fpa_is_negative, a, ctx)
10375 
10376 
z3py.fpIsNegative
def fpIsNegative(a, ctx=None)
Definition: z3py.py:10371

◆ fpIsNormal()

def z3py.fpIsNormal (   a,
  ctx = None 
) 
Create a Z3 floating-point isNormal expression.

Definition at line 10359 of file z3py.py.

10359 def fpIsNormal(a, ctx=None):
10360  """Create a Z3 floating-point isNormal expression.
10361  """
10362  return _mk_fp_unary_pred(Z3_mk_fpa_is_normal, a, ctx)
10363 
10364 
z3py.fpIsNormal
def fpIsNormal(a, ctx=None)
Definition: z3py.py:10359

◆ fpIsPositive()

def z3py.fpIsPositive (   a,
  ctx = None 
) 
Create a Z3 floating-point isPositive expression.

Definition at line 10377 of file z3py.py.

10377 def fpIsPositive(a, ctx=None):
10378  """Create a Z3 floating-point isPositive expression.
10379  """
10380  return _mk_fp_unary_pred(Z3_mk_fpa_is_positive, a, ctx)
10381 
10382 
z3py.fpIsPositive
def fpIsPositive(a, ctx=None)
Definition: z3py.py:10377

◆ fpIsSubnormal()

def z3py.fpIsSubnormal (   a,
  ctx = None 
) 
Create a Z3 floating-point isSubnormal expression.

Definition at line 10365 of file z3py.py.

10365 def fpIsSubnormal(a, ctx=None):
10366  """Create a Z3 floating-point isSubnormal expression.
10367  """
10368  return _mk_fp_unary_pred(Z3_mk_fpa_is_subnormal, a, ctx)
10369 
10370 
z3py.fpIsSubnormal
def fpIsSubnormal(a, ctx=None)
Definition: z3py.py:10365

◆ fpIsZero()

def z3py.fpIsZero (   a,
  ctx = None 
) 
Create a Z3 floating-point isZero expression.

Definition at line 10353 of file z3py.py.

10353 def fpIsZero(a, ctx=None):
10354  """Create a Z3 floating-point isZero expression.
10355  """
10356  return _mk_fp_unary_pred(Z3_mk_fpa_is_zero, a, ctx)
10357 
10358 
z3py.fpIsZero
def fpIsZero(a, ctx=None)
Definition: z3py.py:10353

◆ fpLEQ()

def z3py.fpLEQ (   a,
  b,
  ctx = None 
) 
Create the Z3 floating-point expression `other <= self`.

>>> x, y = FPs('x y', FPSort(8, 24))
>>> fpLEQ(x, y)
x <= y
>>> (x <= y).sexpr()
'(fp.leq x y)'

Definition at line 10400 of file z3py.py.

10400 def fpLEQ(a, b, ctx=None):
10401  """Create the Z3 floating-point expression `other <= self`.
10402 
10403  >>> x, y = FPs('x y', FPSort(8, 24))
10404  >>> fpLEQ(x, y)
10405  x <= y
10406  >>> (x <= y).sexpr()
10407  '(fp.leq x y)'
10408  """
10409  return _mk_fp_bin_pred(Z3_mk_fpa_leq, a, b, ctx)
10410 
10411 
z3py.fpLEQ
def fpLEQ(a, b, ctx=None)
Definition: z3py.py:10400

Referenced by FPRef.__le__().

◆ fpLT()

def z3py.fpLT (   a,
  b,
  ctx = None 
) 
Create the Z3 floating-point expression `other < self`.

>>> x, y = FPs('x y', FPSort(8, 24))
>>> fpLT(x, y)
x < y
>>> (x < y).sexpr()
'(fp.lt x y)'

Definition at line 10388 of file z3py.py.

10388 def fpLT(a, b, ctx=None):
10389  """Create the Z3 floating-point expression `other < self`.
10390 
10391  >>> x, y = FPs('x y', FPSort(8, 24))
10392  >>> fpLT(x, y)
10393  x < y
10394  >>> (x < y).sexpr()
10395  '(fp.lt x y)'
10396  """
10397  return _mk_fp_bin_pred(Z3_mk_fpa_lt, a, b, ctx)
10398 
10399 
z3py.fpLT
def fpLT(a, b, ctx=None)
Definition: z3py.py:10388

Referenced by FPRef.__lt__().

◆ fpMax()

def z3py.fpMax (   a,
  b,
  ctx = None 
) 
Create a Z3 floating-point maximum expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpMax(x, y)
fpMax(x, y)
>>> fpMax(x, y).sort()
FPSort(8, 24)

Definition at line 10297 of file z3py.py.

10297 def fpMax(a, b, ctx=None):
10298  """Create a Z3 floating-point maximum expression.
10299 
10300  >>> s = FPSort(8, 24)
10301  >>> rm = RNE()
10302  >>> x = FP('x', s)
10303  >>> y = FP('y', s)
10304  >>> fpMax(x, y)
10305  fpMax(x, y)
10306  >>> fpMax(x, y).sort()
10307  FPSort(8, 24)
10308  """
10309  return _mk_fp_bin_norm(Z3_mk_fpa_max, a, b, ctx)
10310 
10311 
z3py.fpMax
def fpMax(a, b, ctx=None)
Definition: z3py.py:10297

◆ fpMin()

def z3py.fpMin (   a,
  b,
  ctx = None 
) 
Create a Z3 floating-point minimum expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpMin(x, y)
fpMin(x, y)
>>> fpMin(x, y).sort()
FPSort(8, 24)

Definition at line 10282 of file z3py.py.

10282 def fpMin(a, b, ctx=None):
10283  """Create a Z3 floating-point minimum expression.
10284 
10285  >>> s = FPSort(8, 24)
10286  >>> rm = RNE()
10287  >>> x = FP('x', s)
10288  >>> y = FP('y', s)
10289  >>> fpMin(x, y)
10290  fpMin(x, y)
10291  >>> fpMin(x, y).sort()
10292  FPSort(8, 24)
10293  """
10294  return _mk_fp_bin_norm(Z3_mk_fpa_min, a, b, ctx)
10295 
10296 
z3py.fpMin
def fpMin(a, b, ctx=None)
Definition: z3py.py:10282

◆ fpMinusInfinity()

def z3py.fpMinusInfinity (   s) 
Create a Z3 floating-point -oo term.

Definition at line 9994 of file z3py.py.

9994 def fpMinusInfinity(s):
9995  """Create a Z3 floating-point -oo term."""
9996  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
9997  return FPNumRef(Z3_mk_fpa_inf(s.ctx_ref(), s.ast, True), s.ctx)
9998 
9999 
z3py.fpMinusInfinity
def fpMinusInfinity(s)
Definition: z3py.py:9994

Referenced by FPVal().

◆ fpMinusZero()

def z3py.fpMinusZero (   s) 
Create a Z3 floating-point -0.0 term.

Definition at line 10013 of file z3py.py.

10013 def fpMinusZero(s):
10014  """Create a Z3 floating-point -0.0 term."""
10015  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
10016  return FPNumRef(Z3_mk_fpa_zero(s.ctx_ref(), s.ast, True), s.ctx)
10017 
10018 
Z3_mk_fpa_zero
Z3_ast Z3_API Z3_mk_fpa_zero(Z3_context c, Z3_sort s, bool negative)
Create a floating-point zero of sort s.
z3py.fpMinusZero
def fpMinusZero(s)
Definition: z3py.py:10013

Referenced by FPVal().

◆ fpMul()

def z3py.fpMul (   rm,
  a,
  b,
  ctx = None 
) 
Create a Z3 floating-point multiplication expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpMul(rm, x, y)
x * y
>>> fpMul(rm, x, y).sort()
FPSort(8, 24)

Definition at line 10238 of file z3py.py.

10238 def fpMul(rm, a, b, ctx=None):
10239  """Create a Z3 floating-point multiplication expression.
10240 
10241  >>> s = FPSort(8, 24)
10242  >>> rm = RNE()
10243  >>> x = FP('x', s)
10244  >>> y = FP('y', s)
10245  >>> fpMul(rm, x, y)
10246  x * y
10247  >>> fpMul(rm, x, y).sort()
10248  FPSort(8, 24)
10249  """
10250  return _mk_fp_bin(Z3_mk_fpa_mul, rm, a, b, ctx)
10251 
10252 
z3py.fpMul
def fpMul(rm, a, b, ctx=None)
Definition: z3py.py:10238

Referenced by FPRef.__mul__(), and FPRef.__rmul__().

◆ fpNaN()

def z3py.fpNaN (   s) 
Create a Z3 floating-point NaN term.

>>> s = FPSort(8, 24)
>>> set_fpa_pretty(True)
>>> fpNaN(s)
NaN
>>> pb = get_fpa_pretty()
>>> set_fpa_pretty(False)
>>> fpNaN(s)
fpNaN(FPSort(8, 24))
>>> set_fpa_pretty(pb)

Definition at line 9960 of file z3py.py.

9960 def fpNaN(s):
9961  """Create a Z3 floating-point NaN term.
9962 
9963  >>> s = FPSort(8, 24)
9964  >>> set_fpa_pretty(True)
9965  >>> fpNaN(s)
9966  NaN
9967  >>> pb = get_fpa_pretty()
9968  >>> set_fpa_pretty(False)
9969  >>> fpNaN(s)
9970  fpNaN(FPSort(8, 24))
9971  >>> set_fpa_pretty(pb)
9972  """
9973  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
9974  return FPNumRef(Z3_mk_fpa_nan(s.ctx_ref(), s.ast), s.ctx)
9975 
9976 
Z3_mk_fpa_nan
Z3_ast Z3_API Z3_mk_fpa_nan(Z3_context c, Z3_sort s)
Create a floating-point NaN of sort s.
z3py.fpNaN
def fpNaN(s)
Definition: z3py.py:9960

Referenced by FPVal().

◆ fpNeg()

def z3py.fpNeg (   a,
  ctx = None 
) 
Create a Z3 floating-point addition expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> fpNeg(x)
-x
>>> fpNeg(x).sort()
FPSort(8, 24)

Definition at line 10138 of file z3py.py.

10138 def fpNeg(a, ctx=None):
10139  """Create a Z3 floating-point addition expression.
10140 
10141  >>> s = FPSort(8, 24)
10142  >>> rm = RNE()
10143  >>> x = FP('x', s)
10144  >>> fpNeg(x)
10145  -x
10146  >>> fpNeg(x).sort()
10147  FPSort(8, 24)
10148  """
10149  ctx = _get_ctx(ctx)
10150  [a] = _coerce_fp_expr_list([a], ctx)
10151  return FPRef(Z3_mk_fpa_neg(ctx.ref(), a.as_ast()), ctx)
10152 
10153 
Z3_mk_fpa_neg
Z3_ast Z3_API Z3_mk_fpa_neg(Z3_context c, Z3_ast t)
Floating-point negation.
z3py.fpNeg
def fpNeg(a, ctx=None)
Definition: z3py.py:10138

Referenced by FPRef.__neg__().

◆ fpNEQ()

def z3py.fpNEQ (   a,
  b,
  ctx = None 
) 
Create the Z3 floating-point expression `Not(fpEQ(other, self))`.

>>> x, y = FPs('x y', FPSort(8, 24))
>>> fpNEQ(x, y)
Not(fpEQ(x, y))
>>> (x != y).sexpr()
'(distinct x y)'

Definition at line 10448 of file z3py.py.

10448 def fpNEQ(a, b, ctx=None):
10449  """Create the Z3 floating-point expression `Not(fpEQ(other, self))`.
10450 
10451  >>> x, y = FPs('x y', FPSort(8, 24))
10452  >>> fpNEQ(x, y)
10453  Not(fpEQ(x, y))
10454  >>> (x != y).sexpr()
10455  '(distinct x y)'
10456  """
10457  return Not(fpEQ(a, b, ctx))
10458 
10459 
z3py.Not
def Not(a, ctx=None)
Definition: z3py.py:1815
z3py.fpNEQ
def fpNEQ(a, b, ctx=None)
Definition: z3py.py:10448

◆ fpPlusInfinity()

def z3py.fpPlusInfinity (   s) 
Create a Z3 floating-point +oo term.

>>> s = FPSort(8, 24)
>>> pb = get_fpa_pretty()
>>> set_fpa_pretty(True)
>>> fpPlusInfinity(s)
+oo
>>> set_fpa_pretty(False)
>>> fpPlusInfinity(s)
fpPlusInfinity(FPSort(8, 24))
>>> set_fpa_pretty(pb)

Definition at line 9977 of file z3py.py.

9977 def fpPlusInfinity(s):
9978  """Create a Z3 floating-point +oo term.
9979 
9980  >>> s = FPSort(8, 24)
9981  >>> pb = get_fpa_pretty()
9982  >>> set_fpa_pretty(True)
9983  >>> fpPlusInfinity(s)
9984  +oo
9985  >>> set_fpa_pretty(False)
9986  >>> fpPlusInfinity(s)
9987  fpPlusInfinity(FPSort(8, 24))
9988  >>> set_fpa_pretty(pb)
9989  """
9990  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
9991  return FPNumRef(Z3_mk_fpa_inf(s.ctx_ref(), s.ast, False), s.ctx)
9992 
9993 
z3py.fpPlusInfinity
def fpPlusInfinity(s)
Definition: z3py.py:9977

Referenced by FPVal().

◆ fpPlusZero()

def z3py.fpPlusZero (   s) 
Create a Z3 floating-point +0.0 term.

Definition at line 10007 of file z3py.py.

10007 def fpPlusZero(s):
10008  """Create a Z3 floating-point +0.0 term."""
10009  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
10010  return FPNumRef(Z3_mk_fpa_zero(s.ctx_ref(), s.ast, False), s.ctx)
10011 
10012 
z3py.fpPlusZero
def fpPlusZero(s)
Definition: z3py.py:10007

Referenced by FPVal().

◆ fpRealToFP()

def z3py.fpRealToFP (   rm,
  v,
  sort,
  ctx = None 
) 
Create a Z3 floating-point conversion expression that represents the
conversion from a real term to a floating-point term.

>>> x_r = RealVal(1.5)
>>> x_fp = fpRealToFP(RNE(), x_r, Float32())
>>> x_fp
fpToFP(RNE(), 3/2)
>>> simplify(x_fp)
1.5

Definition at line 10565 of file z3py.py.

10565 def fpRealToFP(rm, v, sort, ctx=None):
10566  """Create a Z3 floating-point conversion expression that represents the
10567  conversion from a real term to a floating-point term.
10568 
10569  >>> x_r = RealVal(1.5)
10570  >>> x_fp = fpRealToFP(RNE(), x_r, Float32())
10571  >>> x_fp
10572  fpToFP(RNE(), 3/2)
10573  >>> simplify(x_fp)
10574  1.5
10575  """
10576  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression.")
10577  _z3_assert(is_real(v), "Second argument must be a Z3 expression or real sort.")
10578  _z3_assert(is_fp_sort(sort), "Third argument must be a Z3 floating-point sort.")
10579  ctx = _get_ctx(ctx)
10580  return FPRef(Z3_mk_fpa_to_fp_real(ctx.ref(), rm.ast, v.ast, sort.ast), ctx)
10581 
10582 
Z3_mk_fpa_to_fp_real
Z3_ast Z3_API Z3_mk_fpa_to_fp_real(Z3_context c, Z3_ast rm, Z3_ast t, Z3_sort s)
Conversion of a term of real sort into a term of FloatingPoint sort.
z3py.fpRealToFP
def fpRealToFP(rm, v, sort, ctx=None)
Definition: z3py.py:10565
z3py.is_real
def is_real(a)
Definition: z3py.py:2705

◆ fpRem()

def z3py.fpRem (   a,
  b,
  ctx = None 
) 
Create a Z3 floating-point remainder expression.

>>> s = FPSort(8, 24)
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpRem(x, y)
fpRem(x, y)
>>> fpRem(x, y).sort()
FPSort(8, 24)

Definition at line 10268 of file z3py.py.

10268 def fpRem(a, b, ctx=None):
10269  """Create a Z3 floating-point remainder expression.
10270 
10271  >>> s = FPSort(8, 24)
10272  >>> x = FP('x', s)
10273  >>> y = FP('y', s)
10274  >>> fpRem(x, y)
10275  fpRem(x, y)
10276  >>> fpRem(x, y).sort()
10277  FPSort(8, 24)
10278  """
10279  return _mk_fp_bin_norm(Z3_mk_fpa_rem, a, b, ctx)
10280 
10281 
z3py.fpRem
def fpRem(a, b, ctx=None)
Definition: z3py.py:10268

Referenced by FPRef.__mod__(), and FPRef.__rmod__().

◆ fpRoundToIntegral()

def z3py.fpRoundToIntegral (   rm,
  a,
  ctx = None 
) 
Create a Z3 floating-point roundToIntegral expression.

Definition at line 10324 of file z3py.py.

10324 def fpRoundToIntegral(rm, a, ctx=None):
10325  """Create a Z3 floating-point roundToIntegral expression.
10326  """
10327  return _mk_fp_unary(Z3_mk_fpa_round_to_integral, rm, a, ctx)
10328 
10329 
z3py.fpRoundToIntegral
def fpRoundToIntegral(rm, a, ctx=None)
Definition: z3py.py:10324

◆ FPs()

def z3py.FPs (   names,
  fpsort,
  ctx = None 
) 
Return an array of floating-point constants.

>>> x, y, z = FPs('x y z', FPSort(8, 24))
>>> x.sort()
FPSort(8, 24)
>>> x.sbits()
24
>>> x.ebits()
8
>>> fpMul(RNE(), fpAdd(RNE(), x, y), z)
x + y * z

Definition at line 10096 of file z3py.py.

10096 def FPs(names, fpsort, ctx=None):
10097  """Return an array of floating-point constants.
10098 
10099  >>> x, y, z = FPs('x y z', FPSort(8, 24))
10100  >>> x.sort()
10101  FPSort(8, 24)
10102  >>> x.sbits()
10103  24
10104  >>> x.ebits()
10105  8
10106  >>> fpMul(RNE(), fpAdd(RNE(), x, y), z)
10107  x + y * z
10108  """
10109  ctx = _get_ctx(ctx)
10110  if isinstance(names, str):
10111  names = names.split(" ")
10112  return [FP(name, fpsort, ctx) for name in names]
10113 
10114 
z3py.FPs
def FPs(names, fpsort, ctx=None)
Definition: z3py.py:10096

◆ fpSignedToFP()

def z3py.fpSignedToFP (   rm,
  v,
  sort,
  ctx = None 
) 
Create a Z3 floating-point conversion expression that represents the
conversion from a signed bit-vector term (encoding an integer) to a floating-point term.

>>> x_signed = BitVecVal(-5, BitVecSort(32))
>>> x_fp = fpSignedToFP(RNE(), x_signed, Float32())
>>> x_fp
fpToFP(RNE(), 4294967291)
>>> simplify(x_fp)
-1.25*(2**2)

Definition at line 10583 of file z3py.py.

10583 def fpSignedToFP(rm, v, sort, ctx=None):
10584  """Create a Z3 floating-point conversion expression that represents the
10585  conversion from a signed bit-vector term (encoding an integer) to a floating-point term.
10586 
10587  >>> x_signed = BitVecVal(-5, BitVecSort(32))
10588  >>> x_fp = fpSignedToFP(RNE(), x_signed, Float32())
10589  >>> x_fp
10590  fpToFP(RNE(), 4294967291)
10591  >>> simplify(x_fp)
10592  -1.25*(2**2)
10593  """
10594  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression.")
10595  _z3_assert(is_bv(v), "Second argument must be a Z3 bit-vector expression")
10596  _z3_assert(is_fp_sort(sort), "Third argument must be a Z3 floating-point sort.")
10597  ctx = _get_ctx(ctx)
10598  return FPRef(Z3_mk_fpa_to_fp_signed(ctx.ref(), rm.ast, v.ast, sort.ast), ctx)
10599 
10600 
Z3_mk_fpa_to_fp_signed
Z3_ast Z3_API Z3_mk_fpa_to_fp_signed(Z3_context c, Z3_ast rm, Z3_ast t, Z3_sort s)
Conversion of a 2's complement signed bit-vector term into a term of FloatingPoint sort.
z3py.fpSignedToFP
def fpSignedToFP(rm, v, sort, ctx=None)
Definition: z3py.py:10583

◆ FPSort()

def z3py.FPSort (   ebits,
  sbits,
  ctx = None 
) 
Return a Z3 floating-point sort of the given sizes. If `ctx=None`, then the global context is used.

>>> Single = FPSort(8, 24)
>>> Double = FPSort(11, 53)
>>> Single
FPSort(8, 24)
>>> x = Const('x', Single)
>>> eq(x, FP('x', FPSort(8, 24)))
True

Definition at line 9901 of file z3py.py.

9901 def FPSort(ebits, sbits, ctx=None):
9902  """Return a Z3 floating-point sort of the given sizes. If `ctx=None`, then the global context is used.
9903 
9904  >>> Single = FPSort(8, 24)
9905  >>> Double = FPSort(11, 53)
9906  >>> Single
9907  FPSort(8, 24)
9908  >>> x = Const('x', Single)
9909  >>> eq(x, FP('x', FPSort(8, 24)))
9910  True
9911  """
9912  ctx = _get_ctx(ctx)
9913  return FPSortRef(Z3_mk_fpa_sort(ctx.ref(), ebits, sbits), ctx)
9914 
9915 
Z3_mk_fpa_sort
Z3_sort Z3_API Z3_mk_fpa_sort(Z3_context c, unsigned ebits, unsigned sbits)
Create a FloatingPoint sort.
z3py.FPSort
def FPSort(ebits, sbits, ctx=None)
Definition: z3py.py:9901

Referenced by get_default_fp_sort(), Context.mkFPSort(), Context.MkFPSort(), Context.MkFPSort128(), Context.mkFPSort128(), Context.MkFPSort16(), Context.mkFPSort16(), Context.MkFPSort32(), Context.mkFPSort32(), Context.MkFPSort64(), Context.mkFPSort64(), Context.MkFPSortDouble(), Context.mkFPSortDouble(), Context.MkFPSortHalf(), Context.mkFPSortHalf(), Context.MkFPSortQuadruple(), Context.mkFPSortQuadruple(), Context.MkFPSortSingle(), and Context.mkFPSortSingle().

◆ fpSqrt()

def z3py.fpSqrt (   rm,
  a,
  ctx = None 
) 
Create a Z3 floating-point square root expression.

Definition at line 10318 of file z3py.py.

10318 def fpSqrt(rm, a, ctx=None):
10319  """Create a Z3 floating-point square root expression.
10320  """
10321  return _mk_fp_unary(Z3_mk_fpa_sqrt, rm, a, ctx)
10322 
10323 
z3py.fpSqrt
def fpSqrt(rm, a, ctx=None)
Definition: z3py.py:10318

◆ fpSub()

def z3py.fpSub (   rm,
  a,
  b,
  ctx = None 
) 
Create a Z3 floating-point subtraction expression.

>>> s = FPSort(8, 24)
>>> rm = RNE()
>>> x = FP('x', s)
>>> y = FP('y', s)
>>> fpSub(rm, x, y)
x - y
>>> fpSub(rm, x, y).sort()
FPSort(8, 24)

Definition at line 10223 of file z3py.py.

10223 def fpSub(rm, a, b, ctx=None):
10224  """Create a Z3 floating-point subtraction expression.
10225 
10226  >>> s = FPSort(8, 24)
10227  >>> rm = RNE()
10228  >>> x = FP('x', s)
10229  >>> y = FP('y', s)
10230  >>> fpSub(rm, x, y)
10231  x - y
10232  >>> fpSub(rm, x, y).sort()
10233  FPSort(8, 24)
10234  """
10235  return _mk_fp_bin(Z3_mk_fpa_sub, rm, a, b, ctx)
10236 
10237 
z3py.fpSub
def fpSub(rm, a, b, ctx=None)
Definition: z3py.py:10223

Referenced by FPRef.__rsub__(), and FPRef.__sub__().

◆ fpToFP()

def z3py.fpToFP (   a1,
  a2 = None,
  a3 = None,
  ctx = None 
) 
Create a Z3 floating-point conversion expression from other term sorts
to floating-point.

From a bit-vector term in IEEE 754-2008 format:
>>> x = FPVal(1.0, Float32())
>>> x_bv = fpToIEEEBV(x)
>>> simplify(fpToFP(x_bv, Float32()))
1

From a floating-point term with different precision:
>>> x = FPVal(1.0, Float32())
>>> x_db = fpToFP(RNE(), x, Float64())
>>> x_db.sort()
FPSort(11, 53)

From a real term:
>>> x_r = RealVal(1.5)
>>> simplify(fpToFP(RNE(), x_r, Float32()))
1.5

From a signed bit-vector term:
>>> x_signed = BitVecVal(-5, BitVecSort(32))
>>> simplify(fpToFP(RNE(), x_signed, Float32()))
-1.25*(2**2)

Definition at line 10489 of file z3py.py.

10489 def fpToFP(a1, a2=None, a3=None, ctx=None):
10490  """Create a Z3 floating-point conversion expression from other term sorts
10491  to floating-point.
10492 
10493  From a bit-vector term in IEEE 754-2008 format:
10494  >>> x = FPVal(1.0, Float32())
10495  >>> x_bv = fpToIEEEBV(x)
10496  >>> simplify(fpToFP(x_bv, Float32()))
10497  1
10498 
10499  From a floating-point term with different precision:
10500  >>> x = FPVal(1.0, Float32())
10501  >>> x_db = fpToFP(RNE(), x, Float64())
10502  >>> x_db.sort()
10503  FPSort(11, 53)
10504 
10505  From a real term:
10506  >>> x_r = RealVal(1.5)
10507  >>> simplify(fpToFP(RNE(), x_r, Float32()))
10508  1.5
10509 
10510  From a signed bit-vector term:
10511  >>> x_signed = BitVecVal(-5, BitVecSort(32))
10512  >>> simplify(fpToFP(RNE(), x_signed, Float32()))
10513  -1.25*(2**2)
10514  """
10515  ctx = _get_ctx(ctx)
10516  if is_bv(a1) and is_fp_sort(a2):
10517  return FPRef(Z3_mk_fpa_to_fp_bv(ctx.ref(), a1.ast, a2.ast), ctx)
10518  elif is_fprm(a1) and is_fp(a2) and is_fp_sort(a3):
10519  return FPRef(Z3_mk_fpa_to_fp_float(ctx.ref(), a1.ast, a2.ast, a3.ast), ctx)
10520  elif is_fprm(a1) and is_real(a2) and is_fp_sort(a3):
10521  return FPRef(Z3_mk_fpa_to_fp_real(ctx.ref(), a1.ast, a2.ast, a3.ast), ctx)
10522  elif is_fprm(a1) and is_bv(a2) and is_fp_sort(a3):
10523  return FPRef(Z3_mk_fpa_to_fp_signed(ctx.ref(), a1.ast, a2.ast, a3.ast), ctx)
10524  else:
10525  raise Z3Exception("Unsupported combination of arguments for conversion to floating-point term.")
10526 
10527 
z3py.fpToFP
def fpToFP(a1, a2=None, a3=None, ctx=None)
Definition: z3py.py:10489

◆ fpToFPUnsigned()

def z3py.fpToFPUnsigned (   rm,
  x,
  s,
  ctx = None 
) 
Create a Z3 floating-point conversion expression, from unsigned bit-vector to floating-point expression.

Definition at line 10619 of file z3py.py.

10619 def fpToFPUnsigned(rm, x, s, ctx=None):
10620  """Create a Z3 floating-point conversion expression, from unsigned bit-vector to floating-point expression."""
10621  if z3_debug():
10622  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression")
10623  _z3_assert(is_bv(x), "Second argument must be a Z3 bit-vector expression")
10624  _z3_assert(is_fp_sort(s), "Third argument must be Z3 floating-point sort")
10625  ctx = _get_ctx(ctx)
10626  return FPRef(Z3_mk_fpa_to_fp_unsigned(ctx.ref(), rm.ast, x.ast, s.ast), ctx)
10627 
10628 
Z3_mk_fpa_to_fp_unsigned
Z3_ast Z3_API Z3_mk_fpa_to_fp_unsigned(Z3_context c, Z3_ast rm, Z3_ast t, Z3_sort s)
Conversion of a 2's complement unsigned bit-vector term into a term of FloatingPoint sort.
z3py.fpToFPUnsigned
def fpToFPUnsigned(rm, x, s, ctx=None)
Definition: z3py.py:10619

◆ fpToIEEEBV()

def z3py.fpToIEEEBV (   x,
  ctx = None 
) 
\brief Conversion of a floating-point term into a bit-vector term in IEEE 754-2008 format.

The size of the resulting bit-vector is automatically determined.

Note that IEEE 754-2008 allows multiple different representations of NaN. This conversion
knows only one NaN and it will always produce the same bit-vector representation of
that NaN.

>>> x = FP('x', FPSort(8, 24))
>>> y = fpToIEEEBV(x)
>>> print(is_fp(x))
True
>>> print(is_bv(y))
True
>>> print(is_fp(y))
False
>>> print(is_bv(x))
False

Definition at line 10693 of file z3py.py.

10693 def fpToIEEEBV(x, ctx=None):
10694  """\brief Conversion of a floating-point term into a bit-vector term in IEEE 754-2008 format.
10695 
10696  The size of the resulting bit-vector is automatically determined.
10697 
10698  Note that IEEE 754-2008 allows multiple different representations of NaN. This conversion
10699  knows only one NaN and it will always produce the same bit-vector representation of
10700  that NaN.
10701 
10702  >>> x = FP('x', FPSort(8, 24))
10703  >>> y = fpToIEEEBV(x)
10704  >>> print(is_fp(x))
10705  True
10706  >>> print(is_bv(y))
10707  True
10708  >>> print(is_fp(y))
10709  False
10710  >>> print(is_bv(x))
10711  False
10712  """
10713  if z3_debug():
10714  _z3_assert(is_fp(x), "First argument must be a Z3 floating-point expression")
10715  ctx = _get_ctx(ctx)
10716  return BitVecRef(Z3_mk_fpa_to_ieee_bv(ctx.ref(), x.ast), ctx)
10717 
10718 
Z3_mk_fpa_to_ieee_bv
Z3_ast Z3_API Z3_mk_fpa_to_ieee_bv(Z3_context c, Z3_ast t)
Conversion of a floating-point term into a bit-vector term in IEEE 754-2008 format.
z3py.fpToIEEEBV
def fpToIEEEBV(x, ctx=None)
Definition: z3py.py:10693

◆ fpToReal()

def z3py.fpToReal (   x,
  ctx = None 
) 
Create a Z3 floating-point conversion expression, from floating-point expression to real.

>>> x = FP('x', FPSort(8, 24))
>>> y = fpToReal(x)
>>> print(is_fp(x))
True
>>> print(is_real(y))
True
>>> print(is_fp(y))
False
>>> print(is_real(x))
False

Definition at line 10673 of file z3py.py.

10673 def fpToReal(x, ctx=None):
10674  """Create a Z3 floating-point conversion expression, from floating-point expression to real.
10675 
10676  >>> x = FP('x', FPSort(8, 24))
10677  >>> y = fpToReal(x)
10678  >>> print(is_fp(x))
10679  True
10680  >>> print(is_real(y))
10681  True
10682  >>> print(is_fp(y))
10683  False
10684  >>> print(is_real(x))
10685  False
10686  """
10687  if z3_debug():
10688  _z3_assert(is_fp(x), "First argument must be a Z3 floating-point expression")
10689  ctx = _get_ctx(ctx)
10690  return ArithRef(Z3_mk_fpa_to_real(ctx.ref(), x.ast), ctx)
10691 
10692 
Z3_mk_fpa_to_real
Z3_ast Z3_API Z3_mk_fpa_to_real(Z3_context c, Z3_ast t)
Conversion of a floating-point term into a real-numbered term.
z3py.fpToReal
def fpToReal(x, ctx=None)
Definition: z3py.py:10673

◆ fpToSBV()

def z3py.fpToSBV (   rm,
  x,
  s,
  ctx = None 
) 
Create a Z3 floating-point conversion expression, from floating-point expression to signed bit-vector.

>>> x = FP('x', FPSort(8, 24))
>>> y = fpToSBV(RTZ(), x, BitVecSort(32))
>>> print(is_fp(x))
True
>>> print(is_bv(y))
True
>>> print(is_fp(y))
False
>>> print(is_bv(x))
False

Definition at line 10629 of file z3py.py.

10629 def fpToSBV(rm, x, s, ctx=None):
10630  """Create a Z3 floating-point conversion expression, from floating-point expression to signed bit-vector.
10631 
10632  >>> x = FP('x', FPSort(8, 24))
10633  >>> y = fpToSBV(RTZ(), x, BitVecSort(32))
10634  >>> print(is_fp(x))
10635  True
10636  >>> print(is_bv(y))
10637  True
10638  >>> print(is_fp(y))
10639  False
10640  >>> print(is_bv(x))
10641  False
10642  """
10643  if z3_debug():
10644  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression")
10645  _z3_assert(is_fp(x), "Second argument must be a Z3 floating-point expression")
10646  _z3_assert(is_bv_sort(s), "Third argument must be Z3 bit-vector sort")
10647  ctx = _get_ctx(ctx)
10648  return BitVecRef(Z3_mk_fpa_to_sbv(ctx.ref(), rm.ast, x.ast, s.size()), ctx)
10649 
10650 
Z3_mk_fpa_to_sbv
Z3_ast Z3_API Z3_mk_fpa_to_sbv(Z3_context c, Z3_ast rm, Z3_ast t, unsigned sz)
Conversion of a floating-point term into a signed bit-vector.
z3py.fpToSBV
def fpToSBV(rm, x, s, ctx=None)
Definition: z3py.py:10629

◆ fpToUBV()

def z3py.fpToUBV (   rm,
  x,
  s,
  ctx = None 
) 
Create a Z3 floating-point conversion expression, from floating-point expression to unsigned bit-vector.

>>> x = FP('x', FPSort(8, 24))
>>> y = fpToUBV(RTZ(), x, BitVecSort(32))
>>> print(is_fp(x))
True
>>> print(is_bv(y))
True
>>> print(is_fp(y))
False
>>> print(is_bv(x))
False

Definition at line 10651 of file z3py.py.

10651 def fpToUBV(rm, x, s, ctx=None):
10652  """Create a Z3 floating-point conversion expression, from floating-point expression to unsigned bit-vector.
10653 
10654  >>> x = FP('x', FPSort(8, 24))
10655  >>> y = fpToUBV(RTZ(), x, BitVecSort(32))
10656  >>> print(is_fp(x))
10657  True
10658  >>> print(is_bv(y))
10659  True
10660  >>> print(is_fp(y))
10661  False
10662  >>> print(is_bv(x))
10663  False
10664  """
10665  if z3_debug():
10666  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression")
10667  _z3_assert(is_fp(x), "Second argument must be a Z3 floating-point expression")
10668  _z3_assert(is_bv_sort(s), "Third argument must be Z3 bit-vector sort")
10669  ctx = _get_ctx(ctx)
10670  return BitVecRef(Z3_mk_fpa_to_ubv(ctx.ref(), rm.ast, x.ast, s.size()), ctx)
10671 
10672 
Z3_mk_fpa_to_ubv
Z3_ast Z3_API Z3_mk_fpa_to_ubv(Z3_context c, Z3_ast rm, Z3_ast t, unsigned sz)
Conversion of a floating-point term into an unsigned bit-vector.
z3py.fpToUBV
def fpToUBV(rm, x, s, ctx=None)
Definition: z3py.py:10651

◆ fpUnsignedToFP()

def z3py.fpUnsignedToFP (   rm,
  v,
  sort,
  ctx = None 
) 
Create a Z3 floating-point conversion expression that represents the
conversion from an unsigned bit-vector term (encoding an integer) to a floating-point term.

>>> x_signed = BitVecVal(-5, BitVecSort(32))
>>> x_fp = fpUnsignedToFP(RNE(), x_signed, Float32())
>>> x_fp
fpToFPUnsigned(RNE(), 4294967291)
>>> simplify(x_fp)
1*(2**32)

Definition at line 10601 of file z3py.py.

10601 def fpUnsignedToFP(rm, v, sort, ctx=None):
10602  """Create a Z3 floating-point conversion expression that represents the
10603  conversion from an unsigned bit-vector term (encoding an integer) to a floating-point term.
10604 
10605  >>> x_signed = BitVecVal(-5, BitVecSort(32))
10606  >>> x_fp = fpUnsignedToFP(RNE(), x_signed, Float32())
10607  >>> x_fp
10608  fpToFPUnsigned(RNE(), 4294967291)
10609  >>> simplify(x_fp)
10610  1*(2**32)
10611  """
10612  _z3_assert(is_fprm(rm), "First argument must be a Z3 floating-point rounding mode expression.")
10613  _z3_assert(is_bv(v), "Second argument must be a Z3 bit-vector expression")
10614  _z3_assert(is_fp_sort(sort), "Third argument must be a Z3 floating-point sort.")
10615  ctx = _get_ctx(ctx)
10616  return FPRef(Z3_mk_fpa_to_fp_unsigned(ctx.ref(), rm.ast, v.ast, sort.ast), ctx)
10617 
10618 
z3py.fpUnsignedToFP
def fpUnsignedToFP(rm, v, sort, ctx=None)
Definition: z3py.py:10601

◆ FPVal()

def z3py.FPVal (   sig,
  exp = None,
  fps = None,
  ctx = None 
) 
Return a floating-point value of value `val` and sort `fps`.
If `ctx=None`, then the global context is used.

>>> v = FPVal(20.0, FPSort(8, 24))
>>> v
1.25*(2**4)
>>> print("0x%.8x" % v.exponent_as_long(False))
0x00000004
>>> v = FPVal(2.25, FPSort(8, 24))
>>> v
1.125*(2**1)
>>> v = FPVal(-2.25, FPSort(8, 24))
>>> v
-1.125*(2**1)
>>> FPVal(-0.0, FPSort(8, 24))
-0.0
>>> FPVal(0.0, FPSort(8, 24))
+0.0
>>> FPVal(+0.0, FPSort(8, 24))
+0.0

Definition at line 10026 of file z3py.py.

10026 def FPVal(sig, exp=None, fps=None, ctx=None):
10027  """Return a floating-point value of value `val` and sort `fps`.
10028  If `ctx=None`, then the global context is used.
10029 
10030  >>> v = FPVal(20.0, FPSort(8, 24))
10031  >>> v
10032  1.25*(2**4)
10033  >>> print("0x%.8x" % v.exponent_as_long(False))
10034  0x00000004
10035  >>> v = FPVal(2.25, FPSort(8, 24))
10036  >>> v
10037  1.125*(2**1)
10038  >>> v = FPVal(-2.25, FPSort(8, 24))
10039  >>> v
10040  -1.125*(2**1)
10041  >>> FPVal(-0.0, FPSort(8, 24))
10042  -0.0
10043  >>> FPVal(0.0, FPSort(8, 24))
10044  +0.0
10045  >>> FPVal(+0.0, FPSort(8, 24))
10046  +0.0
10047  """
10048  ctx = _get_ctx(ctx)
10049  if is_fp_sort(exp):
10050  fps = exp
10051  exp = None
10052  elif fps is None:
10053  fps = _dflt_fps(ctx)
10054  _z3_assert(is_fp_sort(fps), "sort mismatch")
10055  if exp is None:
10056  exp = 0
10057  val = _to_float_str(sig)
10058  if val == "NaN" or val == "nan":
10059  return fpNaN(fps)
10060  elif val == "-0.0":
10061  return fpMinusZero(fps)
10062  elif val == "0.0" or val == "+0.0":
10063  return fpPlusZero(fps)
10064  elif val == "+oo" or val == "+inf" or val == "+Inf":
10065  return fpPlusInfinity(fps)
10066  elif val == "-oo" or val == "-inf" or val == "-Inf":
10067  return fpMinusInfinity(fps)
10068  else:
10069  return FPNumRef(Z3_mk_numeral(ctx.ref(), val, fps.ast), ctx)
10070 
10071 
z3py.FPVal
def FPVal(sig, exp=None, fps=None, ctx=None)
Definition: z3py.py:10026

Referenced by set_default_fp_sort().

◆ fpZero()

def z3py.fpZero (   s,
  negative 
) 
Create a Z3 floating-point +0.0 or -0.0 term.

Definition at line 10019 of file z3py.py.

10019 def fpZero(s, negative):
10020  """Create a Z3 floating-point +0.0 or -0.0 term."""
10021  _z3_assert(isinstance(s, FPSortRef), "sort mismatch")
10022  _z3_assert(isinstance(negative, bool), "expected Boolean flag")
10023  return FPNumRef(Z3_mk_fpa_zero(s.ctx_ref(), s.ast, negative), s.ctx)
10024 
10025 
z3py.fpZero
def fpZero(s, negative)
Definition: z3py.py:10019

◆ FreshBool()

def z3py.FreshBool (   prefix = "b",
  ctx = None 
) 
Return a fresh Boolean constant in the given context using the given prefix.

If `ctx=None`, then the global context is used.

>>> b1 = FreshBool()
>>> b2 = FreshBool()
>>> eq(b1, b2)
False

Definition at line 1771 of file z3py.py.

1771 def FreshBool(prefix="b", ctx=None):
1772  """Return a fresh Boolean constant in the given context using the given prefix.
1773 
1774  If `ctx=None`, then the global context is used.
1775 
1776  >>> b1 = FreshBool()
1777  >>> b2 = FreshBool()
1778  >>> eq(b1, b2)
1779  False
1780  """
1781  ctx = _get_ctx(ctx)
1782  return BoolRef(Z3_mk_fresh_const(ctx.ref(), prefix, BoolSort(ctx).ast), ctx)
1783 
1784 
Z3_mk_fresh_const
Z3_ast Z3_API Z3_mk_fresh_const(Z3_context c, Z3_string prefix, Z3_sort ty)
Declare and create a fresh constant.
z3py.FreshBool
def FreshBool(prefix="b", ctx=None)
Definition: z3py.py:1771

◆ FreshConst()

def z3py.FreshConst (   sort,
  prefix = "c" 
) 
Create a fresh constant of a specified sort

Definition at line 1464 of file z3py.py.

1464 def FreshConst(sort, prefix="c"):
1465  """Create a fresh constant of a specified sort"""
1466  ctx = _get_ctx(sort.ctx)
1467  return _to_expr_ref(Z3_mk_fresh_const(ctx.ref(), prefix, sort.ast), ctx)
1468 
1469 
z3py.FreshConst
def FreshConst(sort, prefix="c")
Definition: z3py.py:1464

◆ FreshFunction()

def z3py.FreshFunction ( sig) 
Create a new fresh Z3 uninterpreted function with the given sorts.

Definition at line 886 of file z3py.py.

886 def FreshFunction(*sig):
887  """Create a new fresh Z3 uninterpreted function with the given sorts.
888  """
889  sig = _get_args(sig)
890  if z3_debug():
891  _z3_assert(len(sig) > 0, "At least two arguments expected")
892  arity = len(sig) - 1
893  rng = sig[arity]
894  if z3_debug():
895  _z3_assert(is_sort(rng), "Z3 sort expected")
896  dom = (z3.Sort * arity)()
897  for i in range(arity):
898  if z3_debug():
899  _z3_assert(is_sort(sig[i]), "Z3 sort expected")
900  dom[i] = sig[i].ast
901  ctx = rng.ctx
902  return FuncDeclRef(Z3_mk_fresh_func_decl(ctx.ref(), "f", arity, dom, rng.ast), ctx)
903 
904 
Z3_mk_fresh_func_decl
Z3_func_decl Z3_API Z3_mk_fresh_func_decl(Z3_context c, Z3_string prefix, unsigned domain_size, Z3_sort const domain[], Z3_sort range)
Declare a fresh constant or function.
z3py.FreshFunction
def FreshFunction(*sig)
Definition: z3py.py:886

◆ FreshInt()

def z3py.FreshInt (   prefix = "x",
  ctx = None 
) 
Return a fresh integer constant in the given context using the given prefix.

>>> x = FreshInt()
>>> y = FreshInt()
>>> eq(x, y)
False
>>> x.sort()
Int

Definition at line 3287 of file z3py.py.

3287 def FreshInt(prefix="x", ctx=None):
3288  """Return a fresh integer constant in the given context using the given prefix.
3289 
3290  >>> x = FreshInt()
3291  >>> y = FreshInt()
3292  >>> eq(x, y)
3293  False
3294  >>> x.sort()
3295  Int
3296  """
3297  ctx = _get_ctx(ctx)
3298  return ArithRef(Z3_mk_fresh_const(ctx.ref(), prefix, IntSort(ctx).ast), ctx)
3299 
3300 
z3py.IntSort
def IntSort(ctx=None)
Definition: z3py.py:3138
z3py.FreshInt
def FreshInt(prefix="x", ctx=None)
Definition: z3py.py:3287

◆ FreshReal()

def z3py.FreshReal (   prefix = "b",
  ctx = None 
) 
Return a fresh real constant in the given context using the given prefix.

>>> x = FreshReal()
>>> y = FreshReal()
>>> eq(x, y)
False
>>> x.sort()
Real

Definition at line 3344 of file z3py.py.

3344 def FreshReal(prefix="b", ctx=None):
3345  """Return a fresh real constant in the given context using the given prefix.
3346 
3347  >>> x = FreshReal()
3348  >>> y = FreshReal()
3349  >>> eq(x, y)
3350  False
3351  >>> x.sort()
3352  Real
3353  """
3354  ctx = _get_ctx(ctx)
3355  return ArithRef(Z3_mk_fresh_const(ctx.ref(), prefix, RealSort(ctx).ast), ctx)
3356 
3357 
z3py.RealSort
def RealSort(ctx=None)
Definition: z3py.py:3155
z3py.FreshReal
def FreshReal(prefix="b", ctx=None)
Definition: z3py.py:3344

◆ Full()

def z3py.Full (   s) 
Create the regular expression that accepts the universal language
>>> e = Full(ReSort(SeqSort(IntSort())))
>>> print(e)
Full(ReSort(Seq(Int)))
>>> e1 = Full(ReSort(StringSort()))
>>> print(e1)
Full(ReSort(String))

Definition at line 10975 of file z3py.py.

10975 def Full(s):
10976  """Create the regular expression that accepts the universal language
10977  >>> e = Full(ReSort(SeqSort(IntSort())))
10978  >>> print(e)
10979  Full(ReSort(Seq(Int)))
10980  >>> e1 = Full(ReSort(StringSort()))
10981  >>> print(e1)
10982  Full(ReSort(String))
10983  """
10984  if isinstance(s, ReSortRef):
10985  return ReRef(Z3_mk_re_full(s.ctx_ref(), s.ast), s.ctx)
10986  raise Z3Exception("Non-sequence, non-regular expression sort passed to Full")
10987 
10988 
10989 
Z3_mk_re_full
Z3_ast Z3_API Z3_mk_re_full(Z3_context c, Z3_sort re)
Create an universal regular expression of sort re.
z3py.Full
def Full(s)
Definition: z3py.py:10975

◆ FullSet()

def z3py.FullSet (   s) 
Create the full set
>>> FullSet(IntSort())
K(Int, True)

Definition at line 4931 of file z3py.py.

4931 def FullSet(s):
4932  """Create the full set
4933  >>> FullSet(IntSort())
4934  K(Int, True)
4935  """
4936  ctx = s.ctx
4937  return ArrayRef(Z3_mk_full_set(ctx.ref(), s.ast), ctx)
4938 
4939 
Z3_mk_full_set
Z3_ast Z3_API Z3_mk_full_set(Z3_context c, Z3_sort domain)
Create the full set.
z3py.FullSet
def FullSet(s)
Definition: z3py.py:4931

◆ Function()

def z3py.Function (   name,
sig 
) 
Create a new Z3 uninterpreted function with the given sorts.

>>> f = Function('f', IntSort(), IntSort())
>>> f(f(0))
f(f(0))

Definition at line 863 of file z3py.py.

863 def Function(name, *sig):
864  """Create a new Z3 uninterpreted function with the given sorts.
865 
866  >>> f = Function('f', IntSort(), IntSort())
867  >>> f(f(0))
868  f(f(0))
869  """
870  sig = _get_args(sig)
871  if z3_debug():
872  _z3_assert(len(sig) > 0, "At least two arguments expected")
873  arity = len(sig) - 1
874  rng = sig[arity]
875  if z3_debug():
876  _z3_assert(is_sort(rng), "Z3 sort expected")
877  dom = (Sort * arity)()
878  for i in range(arity):
879  if z3_debug():
880  _z3_assert(is_sort(sig[i]), "Z3 sort expected")
881  dom[i] = sig[i].ast
882  ctx = rng.ctx
883  return FuncDeclRef(Z3_mk_func_decl(ctx.ref(), to_symbol(name, ctx), arity, dom, rng.ast), ctx)
884 
885 
Z3_mk_func_decl
Z3_func_decl Z3_API Z3_mk_func_decl(Z3_context c, Z3_symbol s, unsigned domain_size, Z3_sort const domain[], Z3_sort range)
Declare a constant or function.
z3py.Function
def Function(name, *sig)
Definition: z3py.py:863

◆ get_as_array_func()

def z3py.get_as_array_func (   n) 
Return the function declaration f associated with a Z3 expression of the form (_ as-array f).

Definition at line 6699 of file z3py.py.

6699 def get_as_array_func(n):
6700  """Return the function declaration f associated with a Z3 expression of the form (_ as-array f)."""
6701  if z3_debug():
6702  _z3_assert(is_as_array(n), "as-array Z3 expression expected.")
6703  return FuncDeclRef(Z3_get_as_array_func_decl(n.ctx.ref(), n.as_ast()), n.ctx)
6704 
Z3_get_as_array_func_decl
Z3_func_decl Z3_API Z3_get_as_array_func_decl(Z3_context c, Z3_ast a)
Return the function declaration f associated with a (_ as_array f) node.
z3py.is_as_array
def is_as_array(n)
Definition: z3py.py:6694
z3py.get_as_array_func
def get_as_array_func(n)
Definition: z3py.py:6699

Referenced by ModelRef.get_interp().

◆ get_ctx()

def z3py.get_ctx (   ctx)

Definition at line 267 of file z3py.py.

267 def get_ctx(ctx):
268  return _get_ctx(ctx)
269 
270 
z3py.get_ctx
def get_ctx(ctx)
Definition: z3py.py:267

◆ get_default_fp_sort()

def z3py.get_default_fp_sort (   ctx = None)

Definition at line 9323 of file z3py.py.

9323 def get_default_fp_sort(ctx=None):
9324  return FPSort(_dflt_fpsort_ebits, _dflt_fpsort_sbits, ctx)
9325 
9326 
z3py.get_default_fp_sort
def get_default_fp_sort(ctx=None)
Definition: z3py.py:9323

Referenced by set_default_fp_sort().

◆ get_default_rounding_mode()

def z3py.get_default_rounding_mode (   ctx = None) 
Retrieves the global default rounding mode.

Definition at line 9290 of file z3py.py.

9290 def get_default_rounding_mode(ctx=None):
9291  """Retrieves the global default rounding mode."""
9292  global _dflt_rounding_mode
9293  if _dflt_rounding_mode == Z3_OP_FPA_RM_TOWARD_ZERO:
9294  return RTZ(ctx)
9295  elif _dflt_rounding_mode == Z3_OP_FPA_RM_TOWARD_NEGATIVE:
9296  return RTN(ctx)
9297  elif _dflt_rounding_mode == Z3_OP_FPA_RM_TOWARD_POSITIVE:
9298  return RTP(ctx)
9299  elif _dflt_rounding_mode == Z3_OP_FPA_RM_NEAREST_TIES_TO_EVEN:
9300  return RNE(ctx)
9301  elif _dflt_rounding_mode == Z3_OP_FPA_RM_NEAREST_TIES_TO_AWAY:
9302  return RNA(ctx)
9303 
9304 
z3py.RNE
def RNE(ctx=None)
Definition: z3py.py:9671
z3py.get_default_rounding_mode
def get_default_rounding_mode(ctx=None)
Definition: z3py.py:9290
z3py.RTZ
def RTZ(ctx=None)
Definition: z3py.py:9711
z3py.RTN
def RTN(ctx=None)
Definition: z3py.py:9701
z3py.RTP
def RTP(ctx=None)
Definition: z3py.py:9691
z3py.RNA
def RNA(ctx=None)
Definition: z3py.py:9681

Referenced by set_default_fp_sort().

◆ get_full_version()

def z3py.get_full_version ( )

Definition at line 101 of file z3py.py.

101 def get_full_version():
102  return Z3_get_full_version()
103 
104 
Z3_get_full_version
Z3_string Z3_API Z3_get_full_version(void)
Return a string that fully describes the version of Z3 in use.
z3py.get_full_version
def get_full_version()
Definition: z3py.py:101

◆ get_map_func()

def z3py.get_map_func (   a) 
Return the function declaration associated with a Z3 map array expression.

>>> f = Function('f', IntSort(), IntSort())
>>> b = Array('b', IntSort(), IntSort())
>>> a  = Map(f, b)
>>> eq(f, get_map_func(a))
True
>>> get_map_func(a)
f
>>> get_map_func(a)(0)
f(0)

Definition at line 4676 of file z3py.py.

4676 def get_map_func(a):
4677  """Return the function declaration associated with a Z3 map array expression.
4678 
4679  >>> f = Function('f', IntSort(), IntSort())
4680  >>> b = Array('b', IntSort(), IntSort())
4681  >>> a = Map(f, b)
4682  >>> eq(f, get_map_func(a))
4683  True
4684  >>> get_map_func(a)
4685  f
4686  >>> get_map_func(a)(0)
4687  f(0)
4688  """
4689  if z3_debug():
4690  _z3_assert(is_map(a), "Z3 array map expression expected.")
4691  return FuncDeclRef(
4692  Z3_to_func_decl(
4693  a.ctx_ref(),
4694  Z3_get_decl_ast_parameter(a.ctx_ref(), a.decl().ast, 0),
4695  ),
4696  ctx=a.ctx,
4697  )
4698 
4699 
Z3_to_func_decl
Z3_func_decl Z3_API Z3_to_func_decl(Z3_context c, Z3_ast a)
Convert an AST into a FUNC_DECL_AST. This is just type casting.
Z3_get_decl_ast_parameter
Z3_ast Z3_API Z3_get_decl_ast_parameter(Z3_context c, Z3_func_decl d, unsigned idx)
Return the expression value associated with an expression parameter.
z3py.is_map
def is_map(a)
Definition: z3py.py:4651
z3py.get_map_func
def get_map_func(a)
Definition: z3py.py:4676

◆ get_param()

def z3py.get_param (   name) 
Return the value of a Z3 global (or module) parameter

>>> get_param('nlsat.reorder')
'true'

Definition at line 307 of file z3py.py.

307 def get_param(name):
308  """Return the value of a Z3 global (or module) parameter
309 
310  >>> get_param('nlsat.reorder')
311  'true'
312  """
313  ptr = (ctypes.c_char_p * 1)()
314  if Z3_global_param_get(str(name), ptr):
315  r = z3core._to_pystr(ptr[0])
316  return r
317  raise Z3Exception("failed to retrieve value for '%s'" % name)
318 
Z3_global_param_get
bool Z3_API Z3_global_param_get(Z3_string param_id, Z3_string_ptr param_value)
Get a global (or module) parameter.
z3py.get_param
def get_param(name)
Definition: z3py.py:307

◆ get_var_index()

def z3py.get_var_index (   a) 
Return the de-Bruijn index of the Z3 bounded variable `a`.

>>> x = Int('x')
>>> y = Int('y')
>>> is_var(x)
False
>>> is_const(x)
True
>>> f = Function('f', IntSort(), IntSort(), IntSort())
>>> # Z3 replaces x and y with bound variables when ForAll is executed.
>>> q = ForAll([x, y], f(x, y) == x + y)
>>> q.body()
f(Var(1), Var(0)) == Var(1) + Var(0)
>>> b = q.body()
>>> b.arg(0)
f(Var(1), Var(0))
>>> v1 = b.arg(0).arg(0)
>>> v2 = b.arg(0).arg(1)
>>> v1
Var(1)
>>> v2
Var(0)
>>> get_var_index(v1)
1
>>> get_var_index(v2)
0

Definition at line 1335 of file z3py.py.

1335 def get_var_index(a):
1336  """Return the de-Bruijn index of the Z3 bounded variable `a`.
1337 
1338  >>> x = Int('x')
1339  >>> y = Int('y')
1340  >>> is_var(x)
1341  False
1342  >>> is_const(x)
1343  True
1344  >>> f = Function('f', IntSort(), IntSort(), IntSort())
1345  >>> # Z3 replaces x and y with bound variables when ForAll is executed.
1346  >>> q = ForAll([x, y], f(x, y) == x + y)
1347  >>> q.body()
1348  f(Var(1), Var(0)) == Var(1) + Var(0)
1349  >>> b = q.body()
1350  >>> b.arg(0)
1351  f(Var(1), Var(0))
1352  >>> v1 = b.arg(0).arg(0)
1353  >>> v2 = b.arg(0).arg(1)
1354  >>> v1
1355  Var(1)
1356  >>> v2
1357  Var(0)
1358  >>> get_var_index(v1)
1359  1
1360  >>> get_var_index(v2)
1361  0
1362  """
1363  if z3_debug():
1364  _z3_assert(is_var(a), "Z3 bound variable expected")
1365  return int(Z3_get_index_value(a.ctx.ref(), a.as_ast()))
1366 
1367 
Z3_get_index_value
unsigned Z3_API Z3_get_index_value(Z3_context c, Z3_ast a)
Return index of de-Bruijn bound variable.
z3py.is_var
def is_var(a)
Definition: z3py.py:1310
z3py.get_var_index
def get_var_index(a)
Definition: z3py.py:1335

◆ get_version()

def z3py.get_version ( )

Definition at line 92 of file z3py.py.

92 def get_version():
93  major = ctypes.c_uint(0)
94  minor = ctypes.c_uint(0)
95  build = ctypes.c_uint(0)
96  rev = ctypes.c_uint(0)
97  Z3_get_version(major, minor, build, rev)
98  return (major.value, minor.value, build.value, rev.value)
99 
100 
Z3_get_version
void Z3_API Z3_get_version(unsigned *major, unsigned *minor, unsigned *build_number, unsigned *revision_number)
Return Z3 version number information.
z3py.get_version
def get_version()
Definition: z3py.py:92

◆ get_version_string()

def z3py.get_version_string ( )

Definition at line 83 of file z3py.py.

83 def get_version_string():
84  major = ctypes.c_uint(0)
85  minor = ctypes.c_uint(0)
86  build = ctypes.c_uint(0)
87  rev = ctypes.c_uint(0)
88  Z3_get_version(major, minor, build, rev)
89  return "%s.%s.%s" % (major.value, minor.value, build.value)
90 
91 
z3py.get_version_string
def get_version_string()
Definition: z3py.py:83

◆ help_simplify()

def z3py.help_simplify ( ) 
Return a string describing all options available for Z3 `simplify` procedure.

Definition at line 8796 of file z3py.py.

8796 def help_simplify():
8797  """Return a string describing all options available for Z3 `simplify` procedure."""
8798  print(Z3_simplify_get_help(main_ctx().ref()))
8799 
8800 
Z3_simplify_get_help
Z3_string Z3_API Z3_simplify_get_help(Z3_context c)
Return a string describing all available parameters.
z3py.help_simplify
def help_simplify()
Definition: z3py.py:8796
z3py.main_ctx
def main_ctx()
Definition: z3py.py:239

◆ If()

def z3py.If (   a,
  b,
  c,
  ctx = None 
) 
Create a Z3 if-then-else expression.

>>> x = Int('x')
>>> y = Int('y')
>>> max = If(x > y, x, y)
>>> max
If(x > y, x, y)
>>> simplify(max)
If(x <= y, y, x)

Definition at line 1381 of file z3py.py.

1381 def If(a, b, c, ctx=None):
1382  """Create a Z3 if-then-else expression.
1383 
1384  >>> x = Int('x')
1385  >>> y = Int('y')
1386  >>> max = If(x > y, x, y)
1387  >>> max
1388  If(x > y, x, y)
1389  >>> simplify(max)
1390  If(x <= y, y, x)
1391  """
1392  if isinstance(a, Probe) or isinstance(b, Tactic) or isinstance(c, Tactic):
1393  return Cond(a, b, c, ctx)
1394  else:
1395  ctx = _get_ctx(_ctx_from_ast_arg_list([a, b, c], ctx))
1396  s = BoolSort(ctx)
1397  a = s.cast(a)
1398  b, c = _coerce_exprs(b, c, ctx)
1399  if z3_debug():
1400  _z3_assert(a.ctx == b.ctx, "Context mismatch")
1401  return _to_expr_ref(Z3_mk_ite(ctx.ref(), a.as_ast(), b.as_ast(), c.as_ast()), ctx)
1402 
1403 
Z3_mk_ite
Z3_ast Z3_API Z3_mk_ite(Z3_context c, Z3_ast t1, Z3_ast t2, Z3_ast t3)
Create an AST node representing an if-then-else: ite(t1, t2, t3).

Referenced by BoolRef.__mul__(), ArithRef.__mul__(), and Abs().

◆ Implies()

def z3py.Implies (   a,
  b,
  ctx = None 
) 
Create a Z3 implies expression.

>>> p, q = Bools('p q')
>>> Implies(p, q)
Implies(p, q)

Definition at line 1785 of file z3py.py.

1785 def Implies(a, b, ctx=None):
1786  """Create a Z3 implies expression.
1787 
1788  >>> p, q = Bools('p q')
1789  >>> Implies(p, q)
1790  Implies(p, q)
1791  """
1792  ctx = _get_ctx(_ctx_from_ast_arg_list([a, b], ctx))
1793  s = BoolSort(ctx)
1794  a = s.cast(a)
1795  b = s.cast(b)
1796  return BoolRef(Z3_mk_implies(ctx.ref(), a.as_ast(), b.as_ast()), ctx)
1797 
1798 
Z3_mk_implies
Z3_ast Z3_API Z3_mk_implies(Z3_context c, Z3_ast t1, Z3_ast t2)
Create an AST node representing t1 implies t2.
z3py.Implies
def Implies(a, b, ctx=None)
Definition: z3py.py:1785

Referenced by Fixedpoint.add_rule(), and Fixedpoint.update_rule().

◆ IndexOf()

def z3py.IndexOf (   s,
  substr,
  offset = None 
) 
Retrieve the index of substring within a string starting at a specified offset.
>>> simplify(IndexOf("abcabc", "bc", 0))
1
>>> simplify(IndexOf("abcabc", "bc", 2))
4

Definition at line 11059 of file z3py.py.

11059 def IndexOf(s, substr, offset=None):
11060  """Retrieve the index of substring within a string starting at a specified offset.
11061  >>> simplify(IndexOf("abcabc", "bc", 0))
11062  1
11063  >>> simplify(IndexOf("abcabc", "bc", 2))
11064  4
11065  """
11066  if offset is None:
11067  offset = IntVal(0)
11068  ctx = None
11069  if is_expr(offset):
11070  ctx = offset.ctx
11071  ctx = _get_ctx2(s, substr, ctx)
11072  s = _coerce_seq(s, ctx)
11073  substr = _coerce_seq(substr, ctx)
11074  if _is_int(offset):
11075  offset = IntVal(offset, ctx)
11076  return ArithRef(Z3_mk_seq_index(s.ctx_ref(), s.as_ast(), substr.as_ast(), offset.as_ast()), s.ctx)
11077 
11078 
Z3_mk_seq_index
Z3_ast Z3_API Z3_mk_seq_index(Z3_context c, Z3_ast s, Z3_ast substr, Z3_ast offset)
Return index of the first occurrence of substr in s starting from offset offset. If s does not contai...
z3py.IndexOf
def IndexOf(s, substr, offset=None)
Definition: z3py.py:11059
z3py.IntVal
def IntVal(val, ctx=None)
Definition: z3py.py:3188

◆ InRe()

def z3py.InRe (   s,
  re 
) 
Create regular expression membership test
>>> re = Union(Re("a"),Re("b"))
>>> print (simplify(InRe("a", re)))
True
>>> print (simplify(InRe("b", re)))
True
>>> print (simplify(InRe("c", re)))
False

Definition at line 11172 of file z3py.py.

11172 def InRe(s, re):
11173  """Create regular expression membership test
11174  >>> re = Union(Re("a"),Re("b"))
11175  >>> print (simplify(InRe("a", re)))
11176  True
11177  >>> print (simplify(InRe("b", re)))
11178  True
11179  >>> print (simplify(InRe("c", re)))
11180  False
11181  """
11182  s = _coerce_seq(s, re.ctx)
11183  return BoolRef(Z3_mk_seq_in_re(s.ctx_ref(), s.as_ast(), re.as_ast()), s.ctx)
11184 
11185 
Z3_mk_seq_in_re
Z3_ast Z3_API Z3_mk_seq_in_re(Z3_context c, Z3_ast seq, Z3_ast re)
Check if seq is in the language generated by the regular expression re.
z3py.InRe
def InRe(s, re)
Definition: z3py.py:11172

◆ Int()

def z3py.Int (   name,
  ctx = None 
) 
Return an integer constant named `name`. If `ctx=None`, then the global context is used.

>>> x = Int('x')
>>> is_int(x)
True
>>> is_int(x + 1)
True

Definition at line 3248 of file z3py.py.

3248 def Int(name, ctx=None):
3249  """Return an integer constant named `name`. If `ctx=None`, then the global context is used.
3250 
3251  >>> x = Int('x')
3252  >>> is_int(x)
3253  True
3254  >>> is_int(x + 1)
3255  True
3256  """
3257  ctx = _get_ctx(ctx)
3258  return ArithRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), IntSort(ctx).ast), ctx)
3259 
3260 
z3py.Int
def Int(name, ctx=None)
Definition: z3py.py:3248

Referenced by Ints(), and IntVector().

◆ Int2BV()

def z3py.Int2BV (   a,
  num_bits 
) 
Return the z3 expression Int2BV(a, num_bits).
It is a bit-vector of width num_bits and represents the
modulo of a by 2^num_bits

Definition at line 3996 of file z3py.py.

3996 def Int2BV(a, num_bits):
3997  """Return the z3 expression Int2BV(a, num_bits).
3998  It is a bit-vector of width num_bits and represents the
3999  modulo of a by 2^num_bits
4000  """
4001  ctx = a.ctx
4002  return BitVecRef(Z3_mk_int2bv(ctx.ref(), num_bits, a.as_ast()), ctx)
4003 
4004 
Z3_mk_int2bv
Z3_ast Z3_API Z3_mk_int2bv(Z3_context c, unsigned n, Z3_ast t1)
Create an n bit bit-vector from the integer argument t1.
z3py.Int2BV
def Int2BV(a, num_bits)
Definition: z3py.py:3996

◆ Intersect()

def z3py.Intersect ( args) 
Create intersection of regular expressions.
>>> re = Intersect(Re("a"), Re("b"), Re("c"))

Definition at line 11206 of file z3py.py.

11206 def Intersect(*args):
11207  """Create intersection of regular expressions.
11208  >>> re = Intersect(Re("a"), Re("b"), Re("c"))
11209  """
11210  args = _get_args(args)
11211  sz = len(args)
11212  if z3_debug():
11213  _z3_assert(sz > 0, "At least one argument expected.")
11214  _z3_assert(all([is_re(a) for a in args]), "All arguments must be regular expressions.")
11215  if sz == 1:
11216  return args[0]
11217  ctx = args[0].ctx
11218  v = (Ast * sz)()
11219  for i in range(sz):
11220  v[i] = args[i].as_ast()
11221  return ReRef(Z3_mk_re_intersect(ctx.ref(), sz, v), ctx)
11222 
11223 
Z3_mk_re_intersect
Z3_ast Z3_API Z3_mk_re_intersect(Z3_context c, unsigned n, Z3_ast const args[])
Create the intersection of the regular languages.
z3py.Intersect
def Intersect(*args)
Definition: z3py.py:11206

◆ Ints()

def z3py.Ints (   names,
  ctx = None 
) 
Return a tuple of Integer constants.

>>> x, y, z = Ints('x y z')
>>> Sum(x, y, z)
x + y + z

Definition at line 3261 of file z3py.py.

3261 def Ints(names, ctx=None):
3262  """Return a tuple of Integer constants.
3263 
3264  >>> x, y, z = Ints('x y z')
3265  >>> Sum(x, y, z)
3266  x + y + z
3267  """
3268  ctx = _get_ctx(ctx)
3269  if isinstance(names, str):
3270  names = names.split(" ")
3271  return [Int(name, ctx) for name in names]
3272 
3273 
z3py.Ints
def Ints(names, ctx=None)
Definition: z3py.py:3261

◆ IntSort()

def z3py.IntSort (   ctx = None) 
Return the integer sort in the given context. If `ctx=None`, then the global context is used.

>>> IntSort()
Int
>>> x = Const('x', IntSort())
>>> is_int(x)
True
>>> x.sort() == IntSort()
True
>>> x.sort() == BoolSort()
False

Definition at line 3138 of file z3py.py.

3138 def IntSort(ctx=None):
3139  """Return the integer sort in the given context. If `ctx=None`, then the global context is used.
3140 
3141  >>> IntSort()
3142  Int
3143  >>> x = Const('x', IntSort())
3144  >>> is_int(x)
3145  True
3146  >>> x.sort() == IntSort()
3147  True
3148  >>> x.sort() == BoolSort()
3149  False
3150  """
3151  ctx = _get_ctx(ctx)
3152  return ArithSortRef(Z3_mk_int_sort(ctx.ref()), ctx)
3153 
3154 
Z3_mk_int_sort
Z3_sort Z3_API Z3_mk_int_sort(Z3_context c)
Create the integer type.

Referenced by FreshInt(), Context.getIntSort(), Int(), IntVal(), and Context.mkIntSort().

◆ IntToStr()

def z3py.IntToStr (   s) 
Convert integer expression to string

Definition at line 11114 of file z3py.py.

11114 def IntToStr(s):
11115  """Convert integer expression to string"""
11116  if not is_expr(s):
11117  s = _py2expr(s)
11118  return SeqRef(Z3_mk_int_to_str(s.ctx_ref(), s.as_ast()), s.ctx)
11119 
11120 
Z3_mk_int_to_str
Z3_ast Z3_API Z3_mk_int_to_str(Z3_context c, Z3_ast s)
Integer to string conversion.
z3py.IntToStr
def IntToStr(s)
Definition: z3py.py:11114

◆ IntVal()

def z3py.IntVal (   val,
  ctx = None 
) 
Return a Z3 integer value. If `ctx=None`, then the global context is used.

>>> IntVal(1)
1
>>> IntVal("100")
100

Definition at line 3188 of file z3py.py.

3188 def IntVal(val, ctx=None):
3189  """Return a Z3 integer value. If `ctx=None`, then the global context is used.
3190 
3191  >>> IntVal(1)
3192  1
3193  >>> IntVal("100")
3194  100
3195  """
3196  ctx = _get_ctx(ctx)
3197  return IntNumRef(Z3_mk_numeral(ctx.ref(), _to_int_str(val), IntSort(ctx).ast), ctx)
3198 
3199 

Referenced by SeqRef.__getitem__(), BoolRef.__mul__(), SeqRef.at(), AlgebraicNumRef.index(), and IndexOf().

◆ IntVector()

def z3py.IntVector (   prefix,
  sz,
  ctx = None 
) 
Return a list of integer constants of size `sz`.

>>> X = IntVector('x', 3)
>>> X
[x__0, x__1, x__2]
>>> Sum(X)
x__0 + x__1 + x__2

Definition at line 3274 of file z3py.py.

3274 def IntVector(prefix, sz, ctx=None):
3275  """Return a list of integer constants of size `sz`.
3276 
3277  >>> X = IntVector('x', 3)
3278  >>> X
3279  [x__0, x__1, x__2]
3280  >>> Sum(X)
3281  x__0 + x__1 + x__2
3282  """
3283  ctx = _get_ctx(ctx)
3284  return [Int("%s__%s" % (prefix, i), ctx) for i in range(sz)]
3285 
3286 
z3py.IntVector
def IntVector(prefix, sz, ctx=None)
Definition: z3py.py:3274

◆ is_add()

def z3py.is_add (   a) 
Return `True` if `a` is an expression of the form b + c.

>>> x, y = Ints('x y')
>>> is_add(x + y)
True
>>> is_add(x - y)
False

Definition at line 2792 of file z3py.py.

2792 def is_add(a):
2793  """Return `True` if `a` is an expression of the form b + c.
2794 
2795  >>> x, y = Ints('x y')
2796  >>> is_add(x + y)
2797  True
2798  >>> is_add(x - y)
2799  False
2800  """
2801  return is_app_of(a, Z3_OP_ADD)
2802 
2803 
z3py.is_add
def is_add(a)
Definition: z3py.py:2792
z3py.is_app_of
def is_app_of(a, k)
Definition: z3py.py:1368

◆ is_algebraic_value()

def z3py.is_algebraic_value (   a) 
Return `True` if `a` is an algebraic value of sort Real.

>>> is_algebraic_value(RealVal("3/5"))
False
>>> n = simplify(Sqrt(2))
>>> n
1.4142135623?
>>> is_algebraic_value(n)
True

Definition at line 2778 of file z3py.py.

2778 def is_algebraic_value(a):
2779  """Return `True` if `a` is an algebraic value of sort Real.
2780 
2781  >>> is_algebraic_value(RealVal("3/5"))
2782  False
2783  >>> n = simplify(Sqrt(2))
2784  >>> n
2785  1.4142135623?
2786  >>> is_algebraic_value(n)
2787  True
2788  """
2789  return is_arith(a) and a.is_real() and _is_algebraic(a.ctx, a.as_ast())
2790 
2791 
z3py.is_algebraic_value
def is_algebraic_value(a)
Definition: z3py.py:2778
z3py.is_arith
def is_arith(a)
Definition: z3py.py:2665

◆ is_and()

def z3py.is_and (   a) 
Return `True` if `a` is a Z3 and expression.

>>> p, q = Bools('p q')
>>> is_and(And(p, q))
True
>>> is_and(Or(p, q))
False

Definition at line 1621 of file z3py.py.

1621 def is_and(a):
1622  """Return `True` if `a` is a Z3 and expression.
1623 
1624  >>> p, q = Bools('p q')
1625  >>> is_and(And(p, q))
1626  True
1627  >>> is_and(Or(p, q))
1628  False
1629  """
1630  return is_app_of(a, Z3_OP_AND)
1631 
1632 
z3py.is_and
def is_and(a)
Definition: z3py.py:1621

◆ is_app()

def z3py.is_app (   a) 
Return `True` if `a` is a Z3 function application.

Note that, constants are function applications with 0 arguments.

>>> a = Int('a')
>>> is_app(a)
True
>>> is_app(a + 1)
True
>>> is_app(IntSort())
False
>>> is_app(1)
False
>>> is_app(IntVal(1))
True
>>> x = Int('x')
>>> is_app(ForAll(x, x >= 0))
False

Definition at line 1265 of file z3py.py.

1265 def is_app(a):
1266  """Return `True` if `a` is a Z3 function application.
1267 
1268  Note that, constants are function applications with 0 arguments.
1269 
1270  >>> a = Int('a')
1271  >>> is_app(a)
1272  True
1273  >>> is_app(a + 1)
1274  True
1275  >>> is_app(IntSort())
1276  False
1277  >>> is_app(1)
1278  False
1279  >>> is_app(IntVal(1))
1280  True
1281  >>> x = Int('x')
1282  >>> is_app(ForAll(x, x >= 0))
1283  False
1284  """
1285  if not isinstance(a, ExprRef):
1286  return False
1287  k = _ast_kind(a.ctx, a)
1288  return k == Z3_NUMERAL_AST or k == Z3_APP_AST
1289 
1290 
z3py.is_app
def is_app(a)
Definition: z3py.py:1265

Referenced by ExprRef.arg(), ExprRef.children(), ExprRef.decl(), is_app_of(), is_const(), is_quantifier(), Lambda(), ExprRef.num_args(), and RecAddDefinition().

◆ is_app_of()

def z3py.is_app_of (   a,
  k 
) 
Return `True` if `a` is an application of the given kind `k`.

>>> x = Int('x')
>>> n = x + 1
>>> is_app_of(n, Z3_OP_ADD)
True
>>> is_app_of(n, Z3_OP_MUL)
False

Definition at line 1368 of file z3py.py.

1368 def is_app_of(a, k):
1369  """Return `True` if `a` is an application of the given kind `k`.
1370 
1371  >>> x = Int('x')
1372  >>> n = x + 1
1373  >>> is_app_of(n, Z3_OP_ADD)
1374  True
1375  >>> is_app_of(n, Z3_OP_MUL)
1376  False
1377  """
1378  return is_app(a) and a.decl().kind() == k
1379 
1380 

Referenced by is_add(), is_and(), is_const_array(), is_default(), is_distinct(), is_div(), is_eq(), is_false(), is_ge(), is_gt(), is_idiv(), is_implies(), is_is_int(), is_K(), is_le(), is_lt(), is_map(), is_mod(), is_mul(), is_not(), is_or(), is_select(), is_store(), is_sub(), is_to_int(), is_to_real(), and is_true().

◆ is_arith()

def z3py.is_arith (   a) 
Return `True` if `a` is an arithmetical expression.

>>> x = Int('x')
>>> is_arith(x)
True
>>> is_arith(x + 1)
True
>>> is_arith(1)
False
>>> is_arith(IntVal(1))
True
>>> y = Real('y')
>>> is_arith(y)
True
>>> is_arith(y + 1)
True

Definition at line 2665 of file z3py.py.

2665 def is_arith(a):
2666  """Return `True` if `a` is an arithmetical expression.
2667 
2668  >>> x = Int('x')
2669  >>> is_arith(x)
2670  True
2671  >>> is_arith(x + 1)
2672  True
2673  >>> is_arith(1)
2674  False
2675  >>> is_arith(IntVal(1))
2676  True
2677  >>> y = Real('y')
2678  >>> is_arith(y)
2679  True
2680  >>> is_arith(y + 1)
2681  True
2682  """
2683  return isinstance(a, ArithRef)
2684 
2685 

Referenced by is_algebraic_value(), is_int(), is_int_value(), is_rational_value(), and is_real().

◆ is_arith_sort()

def z3py.is_arith_sort (   s) 
Return `True` if s is an arithmetical sort (type).

>>> is_arith_sort(IntSort())
True
>>> is_arith_sort(RealSort())
True
>>> is_arith_sort(BoolSort())
False
>>> n = Int('x') + 1
>>> is_arith_sort(n.sort())
True

Definition at line 2364 of file z3py.py.

2364 def is_arith_sort(s):
2365  """Return `True` if s is an arithmetical sort (type).
2366 
2367  >>> is_arith_sort(IntSort())
2368  True
2369  >>> is_arith_sort(RealSort())
2370  True
2371  >>> is_arith_sort(BoolSort())
2372  False
2373  >>> n = Int('x') + 1
2374  >>> is_arith_sort(n.sort())
2375  True
2376  """
2377  return isinstance(s, ArithSortRef)
2378 
2379 
z3py.is_arith_sort
def is_arith_sort(s)
Definition: z3py.py:2364

Referenced by ArithSortRef.subsort().

◆ is_array()

def z3py.is_array (   a) 
Return `True` if `a` is a Z3 array expression.

>>> a = Array('a', IntSort(), IntSort())
>>> is_array(a)
True
>>> is_array(Store(a, 0, 1))
True
>>> is_array(a[0])
False

Definition at line 4611 of file z3py.py.

4611 def is_array(a):
4612  """Return `True` if `a` is a Z3 array expression.
4613 
4614  >>> a = Array('a', IntSort(), IntSort())
4615  >>> is_array(a)
4616  True
4617  >>> is_array(Store(a, 0, 1))
4618  True
4619  >>> is_array(a[0])
4620  False
4621  """
4622  return isinstance(a, ArrayRef)
4623 
4624 

Referenced by Ext(), and Map().

◆ is_array_sort()

def z3py.is_array_sort (   a)

Definition at line 4607 of file z3py.py.

4607 def is_array_sort(a):
4608  return Z3_get_sort_kind(a.ctx.ref(), Z3_get_sort(a.ctx.ref(), a.ast)) == Z3_ARRAY_SORT
4609 
4610 
Z3_get_sort_kind
Z3_sort_kind Z3_API Z3_get_sort_kind(Z3_context c, Z3_sort t)
Return the sort kind (e.g., array, tuple, int, bool, etc).
Z3_get_sort
Z3_sort Z3_API Z3_get_sort(Z3_context c, Z3_ast a)
Return the sort of an AST node.

Referenced by Default(), Ext(), Select(), and Update().

◆ is_as_array()

def z3py.is_as_array (   n) 
Return true if n is a Z3 expression of the form (_ as-array f).

Definition at line 6694 of file z3py.py.

6694 def is_as_array(n):
6695  """Return true if n is a Z3 expression of the form (_ as-array f)."""
6696  return isinstance(n, ExprRef) and Z3_is_as_array(n.ctx.ref(), n.as_ast())
6697 
6698 
Z3_is_as_array
bool Z3_API Z3_is_as_array(Z3_context c, Z3_ast a)
The (_ as-array f) AST node is a construct for assigning interpretations for arrays in Z3....

Referenced by get_as_array_func(), and ModelRef.get_interp().

◆ is_ast()

def z3py.is_ast (   a) 
Return `True` if `a` is an AST node.

>>> is_ast(10)
False
>>> is_ast(IntVal(10))
True
>>> is_ast(Int('x'))
True
>>> is_ast(BoolSort())
True
>>> is_ast(Function('f', IntSort(), IntSort()))
True
>>> is_ast("x")
False
>>> is_ast(Solver())
False

Definition at line 451 of file z3py.py.

451 def is_ast(a):
452  """Return `True` if `a` is an AST node.
453 
454  >>> is_ast(10)
455  False
456  >>> is_ast(IntVal(10))
457  True
458  >>> is_ast(Int('x'))
459  True
460  >>> is_ast(BoolSort())
461  True
462  >>> is_ast(Function('f', IntSort(), IntSort()))
463  True
464  >>> is_ast("x")
465  False
466  >>> is_ast(Solver())
467  False
468  """
469  return isinstance(a, AstRef)
470 
471 

Referenced by eq(), AstRef.eq(), and ReSort().

◆ is_bool()

def z3py.is_bool (   a) 
Return `True` if `a` is a Z3 Boolean expression.

>>> p = Bool('p')
>>> is_bool(p)
True
>>> q = Bool('q')
>>> is_bool(And(p, q))
True
>>> x = Real('x')
>>> is_bool(x)
False
>>> is_bool(x == 0)
True

Definition at line 1571 of file z3py.py.

1571 def is_bool(a):
1572  """Return `True` if `a` is a Z3 Boolean expression.
1573 
1574  >>> p = Bool('p')
1575  >>> is_bool(p)
1576  True
1577  >>> q = Bool('q')
1578  >>> is_bool(And(p, q))
1579  True
1580  >>> x = Real('x')
1581  >>> is_bool(x)
1582  False
1583  >>> is_bool(x == 0)
1584  True
1585  """
1586  return isinstance(a, BoolRef)
1587 
1588 
z3py.is_bool
def is_bool(a)
Definition: z3py.py:1571

Referenced by is_quantifier(), and prove().

◆ is_bv()

def z3py.is_bv (   a) 
Return `True` if `a` is a Z3 bit-vector expression.

>>> b = BitVec('b', 32)
>>> is_bv(b)
True
>>> is_bv(b + 10)
True
>>> is_bv(Int('x'))
False

Definition at line 3944 of file z3py.py.

3944 def is_bv(a):
3945  """Return `True` if `a` is a Z3 bit-vector expression.
3946 
3947  >>> b = BitVec('b', 32)
3948  >>> is_bv(b)
3949  True
3950  >>> is_bv(b + 10)
3951  True
3952  >>> is_bv(Int('x'))
3953  False
3954  """
3955  return isinstance(a, BitVecRef)
3956 
3957 

Referenced by BV2Int(), BVRedAnd(), BVRedOr(), BVSNegNoOverflow(), Concat(), Extract(), fpBVToFP(), fpFP(), fpSignedToFP(), fpToFP(), fpToFPUnsigned(), fpUnsignedToFP(), is_bv_value(), Product(), RepeatBitVec(), SignExt(), Sum(), and ZeroExt().

◆ is_bv_sort()

def z3py.is_bv_sort (   s) 
Return True if `s` is a Z3 bit-vector sort.

>>> is_bv_sort(BitVecSort(32))
True
>>> is_bv_sort(IntSort())
False

Definition at line 3476 of file z3py.py.

3476 def is_bv_sort(s):
3477  """Return True if `s` is a Z3 bit-vector sort.
3478 
3479  >>> is_bv_sort(BitVecSort(32))
3480  True
3481  >>> is_bv_sort(IntSort())
3482  False
3483  """
3484  return isinstance(s, BitVecSortRef)
3485 
3486 

Referenced by BitVecVal(), fpToSBV(), fpToUBV(), and BitVecSortRef.subsort().

◆ is_bv_value()

def z3py.is_bv_value (   a) 
Return `True` if `a` is a Z3 bit-vector numeral value.

>>> b = BitVec('b', 32)
>>> is_bv_value(b)
False
>>> b = BitVecVal(10, 32)
>>> b
10
>>> is_bv_value(b)
True

Definition at line 3958 of file z3py.py.

3958 def is_bv_value(a):
3959  """Return `True` if `a` is a Z3 bit-vector numeral value.
3960 
3961  >>> b = BitVec('b', 32)
3962  >>> is_bv_value(b)
3963  False
3964  >>> b = BitVecVal(10, 32)
3965  >>> b
3966  10
3967  >>> is_bv_value(b)
3968  True
3969  """
3970  return is_bv(a) and _is_numeral(a.ctx, a.as_ast())
3971 
3972 
z3py.is_bv_value
def is_bv_value(a)
Definition: z3py.py:3958

◆ is_const()

def z3py.is_const (   a) 
Return `True` if `a` is Z3 constant/variable expression.

>>> a = Int('a')
>>> is_const(a)
True
>>> is_const(a + 1)
False
>>> is_const(1)
False
>>> is_const(IntVal(1))
True
>>> x = Int('x')
>>> is_const(ForAll(x, x >= 0))
False

Definition at line 1291 of file z3py.py.

1291 def is_const(a):
1292  """Return `True` if `a` is Z3 constant/variable expression.
1293 
1294  >>> a = Int('a')
1295  >>> is_const(a)
1296  True
1297  >>> is_const(a + 1)
1298  False
1299  >>> is_const(1)
1300  False
1301  >>> is_const(IntVal(1))
1302  True
1303  >>> x = Int('x')
1304  >>> is_const(ForAll(x, x >= 0))
1305  False
1306  """
1307  return is_app(a) and a.num_args() == 0
1308 
1309 
z3py.is_const
def is_const(a)
Definition: z3py.py:1291

Referenced by ModelRef.__getitem__(), Solver.assert_and_track(), Optimize.assert_and_track(), ModelRef.get_interp(), is_quantifier(), and prove().

◆ is_const_array()

def z3py.is_const_array (   a) 
Return `True` if `a` is a Z3 constant array.

>>> a = K(IntSort(), 10)
>>> is_const_array(a)
True
>>> a = Array('a', IntSort(), IntSort())
>>> is_const_array(a)
False

Definition at line 4625 of file z3py.py.

4625 def is_const_array(a):
4626  """Return `True` if `a` is a Z3 constant array.
4627 
4628  >>> a = K(IntSort(), 10)
4629  >>> is_const_array(a)
4630  True
4631  >>> a = Array('a', IntSort(), IntSort())
4632  >>> is_const_array(a)
4633  False
4634  """
4635  return is_app_of(a, Z3_OP_CONST_ARRAY)
4636 
4637 
z3py.is_const_array
def is_const_array(a)
Definition: z3py.py:4625

◆ is_default()

def z3py.is_default (   a) 
Return `True` if `a` is a Z3 default array expression.
>>> d = Default(K(IntSort(), 10))
>>> is_default(d)
True

Definition at line 4667 of file z3py.py.

4667 def is_default(a):
4668  """Return `True` if `a` is a Z3 default array expression.
4669  >>> d = Default(K(IntSort(), 10))
4670  >>> is_default(d)
4671  True
4672  """
4673  return is_app_of(a, Z3_OP_ARRAY_DEFAULT)
4674 
4675 
z3py.is_default
def is_default(a)
Definition: z3py.py:4667

◆ is_distinct()

def z3py.is_distinct (   a) 
Return `True` if `a` is a Z3 distinct expression.

>>> x, y, z = Ints('x y z')
>>> is_distinct(x == y)
False
>>> is_distinct(Distinct(x, y, z))
True

Definition at line 1679 of file z3py.py.

1679 def is_distinct(a):
1680  """Return `True` if `a` is a Z3 distinct expression.
1681 
1682  >>> x, y, z = Ints('x y z')
1683  >>> is_distinct(x == y)
1684  False
1685  >>> is_distinct(Distinct(x, y, z))
1686  True
1687  """
1688  return is_app_of(a, Z3_OP_DISTINCT)
1689 
1690 
z3py.is_distinct
def is_distinct(a)
Definition: z3py.py:1679

◆ is_div()

def z3py.is_div (   a) 
Return `True` if `a` is an expression of the form b / c.

>>> x, y = Reals('x y')
>>> is_div(x / y)
True
>>> is_div(x + y)
False
>>> x, y = Ints('x y')
>>> is_div(x / y)
False
>>> is_idiv(x / y)
True

Definition at line 2828 of file z3py.py.

2828 def is_div(a):
2829  """Return `True` if `a` is an expression of the form b / c.
2830 
2831  >>> x, y = Reals('x y')
2832  >>> is_div(x / y)
2833  True
2834  >>> is_div(x + y)
2835  False
2836  >>> x, y = Ints('x y')
2837  >>> is_div(x / y)
2838  False
2839  >>> is_idiv(x / y)
2840  True
2841  """
2842  return is_app_of(a, Z3_OP_DIV)
2843 
2844 
z3py.is_div
def is_div(a)
Definition: z3py.py:2828

◆ is_eq()

def z3py.is_eq (   a) 
Return `True` if `a` is a Z3 equality expression.

>>> x, y = Ints('x y')
>>> is_eq(x == y)
True

Definition at line 1669 of file z3py.py.

1669 def is_eq(a):
1670  """Return `True` if `a` is a Z3 equality expression.
1671 
1672  >>> x, y = Ints('x y')
1673  >>> is_eq(x == y)
1674  True
1675  """
1676  return is_app_of(a, Z3_OP_EQ)
1677 
1678 
z3py.is_eq
def is_eq(a)
Definition: z3py.py:1669

Referenced by AstRef.__bool__().

◆ is_expr()

def z3py.is_expr (   a) 
Return `True` if `a` is a Z3 expression.

>>> a = Int('a')
>>> is_expr(a)
True
>>> is_expr(a + 1)
True
>>> is_expr(IntSort())
False
>>> is_expr(1)
False
>>> is_expr(IntVal(1))
True
>>> x = Int('x')
>>> is_expr(ForAll(x, x >= 0))
True
>>> is_expr(FPVal(1.0))
True

Definition at line 1242 of file z3py.py.

1242 def is_expr(a):
1243  """Return `True` if `a` is a Z3 expression.
1244 
1245  >>> a = Int('a')
1246  >>> is_expr(a)
1247  True
1248  >>> is_expr(a + 1)
1249  True
1250  >>> is_expr(IntSort())
1251  False
1252  >>> is_expr(1)
1253  False
1254  >>> is_expr(IntVal(1))
1255  True
1256  >>> x = Int('x')
1257  >>> is_expr(ForAll(x, x >= 0))
1258  True
1259  >>> is_expr(FPVal(1.0))
1260  True
1261  """
1262  return isinstance(a, ExprRef)
1263 
1264 

Referenced by SeqRef.__gt__(), SortRef.cast(), BoolSortRef.cast(), ArithSortRef.cast(), BitVecSortRef.cast(), FPSortRef.cast(), Cbrt(), CharFromBv(), CharIsDigit(), Concat(), deserialize(), AlgebraicNumRef.index(), IndexOf(), IntToStr(), is_quantifier(), is_var(), K(), MultiPattern(), Replace(), simplify(), Sqrt(), StrFromCode(), StrToCode(), substitute(), substitute_funs(), substitute_vars(), and ModelRef.update_value().

◆ is_false()

def z3py.is_false (   a) 
Return `True` if `a` is the Z3 false expression.

>>> p = Bool('p')
>>> is_false(p)
False
>>> is_false(False)
False
>>> is_false(BoolVal(False))
True

Definition at line 1607 of file z3py.py.

1607 def is_false(a):
1608  """Return `True` if `a` is the Z3 false expression.
1609 
1610  >>> p = Bool('p')
1611  >>> is_false(p)
1612  False
1613  >>> is_false(False)
1614  False
1615  >>> is_false(BoolVal(False))
1616  True
1617  """
1618  return is_app_of(a, Z3_OP_FALSE)
1619 
1620 
z3py.is_false
def is_false(a)
Definition: z3py.py:1607

Referenced by AstRef.__bool__().

◆ is_finite_domain()

def z3py.is_finite_domain (   a) 
Return `True` if `a` is a Z3 finite-domain expression.

>>> s = FiniteDomainSort('S', 100)
>>> b = Const('b', s)
>>> is_finite_domain(b)
True
>>> is_finite_domain(Int('x'))
False

Definition at line 7747 of file z3py.py.

7747 def is_finite_domain(a):
7748  """Return `True` if `a` is a Z3 finite-domain expression.
7749 
7750  >>> s = FiniteDomainSort('S', 100)
7751  >>> b = Const('b', s)
7752  >>> is_finite_domain(b)
7753  True
7754  >>> is_finite_domain(Int('x'))
7755  False
7756  """
7757  return isinstance(a, FiniteDomainRef)
7758 
7759 
z3py.is_finite_domain
def is_finite_domain(a)
Definition: z3py.py:7747

Referenced by is_finite_domain_value().

◆ is_finite_domain_sort()

def z3py.is_finite_domain_sort (   s) 
Return True if `s` is a Z3 finite-domain sort.

>>> is_finite_domain_sort(FiniteDomainSort('S', 100))
True
>>> is_finite_domain_sort(IntSort())
False

Definition at line 7724 of file z3py.py.

7724 def is_finite_domain_sort(s):
7725  """Return True if `s` is a Z3 finite-domain sort.
7726 
7727  >>> is_finite_domain_sort(FiniteDomainSort('S', 100))
7728  True
7729  >>> is_finite_domain_sort(IntSort())
7730  False
7731  """
7732  return isinstance(s, FiniteDomainSortRef)
7733 
7734 

Referenced by FiniteDomainVal().

◆ is_finite_domain_value()

def z3py.is_finite_domain_value (   a) 
Return `True` if `a` is a Z3 finite-domain value.

>>> s = FiniteDomainSort('S', 100)
>>> b = Const('b', s)
>>> is_finite_domain_value(b)
False
>>> b = FiniteDomainVal(10, s)
>>> b
10
>>> is_finite_domain_value(b)
True

Definition at line 7801 of file z3py.py.

7801 def is_finite_domain_value(a):
7802  """Return `True` if `a` is a Z3 finite-domain value.
7803 
7804  >>> s = FiniteDomainSort('S', 100)
7805  >>> b = Const('b', s)
7806  >>> is_finite_domain_value(b)
7807  False
7808  >>> b = FiniteDomainVal(10, s)
7809  >>> b
7810  10
7811  >>> is_finite_domain_value(b)
7812  True
7813  """
7814  return is_finite_domain(a) and _is_numeral(a.ctx, a.as_ast())
7815 
7816 
z3py.is_finite_domain_value
def is_finite_domain_value(a)
Definition: z3py.py:7801

◆ is_fp()

def z3py.is_fp (   a) 
Return `True` if `a` is a Z3 floating-point expression.

>>> b = FP('b', FPSort(8, 24))
>>> is_fp(b)
True
>>> is_fp(b + 1.0)
True
>>> is_fp(Int('x'))
False

Definition at line 9872 of file z3py.py.

9872 def is_fp(a):
9873  """Return `True` if `a` is a Z3 floating-point expression.
9874 
9875  >>> b = FP('b', FPSort(8, 24))
9876  >>> is_fp(b)
9877  True
9878  >>> is_fp(b + 1.0)
9879  True
9880  >>> is_fp(Int('x'))
9881  False
9882  """
9883  return isinstance(a, FPRef)
9884 
9885 

Referenced by fpFPToFP(), fpIsPositive(), fpNeg(), fpToFP(), fpToIEEEBV(), fpToReal(), fpToSBV(), fpToUBV(), is_fp_value(), and set_default_fp_sort().

◆ is_fp_sort()

def z3py.is_fp_sort (   s) 
Return True if `s` is a Z3 floating-point sort.

>>> is_fp_sort(FPSort(8, 24))
True
>>> is_fp_sort(IntSort())
False

Definition at line 9456 of file z3py.py.

9456 def is_fp_sort(s):
9457  """Return True if `s` is a Z3 floating-point sort.
9458 
9459  >>> is_fp_sort(FPSort(8, 24))
9460  True
9461  >>> is_fp_sort(IntSort())
9462  False
9463  """
9464  return isinstance(s, FPSortRef)
9465 
9466 

Referenced by fpBVToFP(), fpFPToFP(), fpRealToFP(), fpSignedToFP(), fpToFP(), fpToFPUnsigned(), fpUnsignedToFP(), and FPVal().

◆ is_fp_value()

def z3py.is_fp_value (   a) 
Return `True` if `a` is a Z3 floating-point numeral value.

>>> b = FP('b', FPSort(8, 24))
>>> is_fp_value(b)
False
>>> b = FPVal(1.0, FPSort(8, 24))
>>> b
1
>>> is_fp_value(b)
True

Definition at line 9886 of file z3py.py.

9886 def is_fp_value(a):
9887  """Return `True` if `a` is a Z3 floating-point numeral value.
9888 
9889  >>> b = FP('b', FPSort(8, 24))
9890  >>> is_fp_value(b)
9891  False
9892  >>> b = FPVal(1.0, FPSort(8, 24))
9893  >>> b
9894  1
9895  >>> is_fp_value(b)
9896  True
9897  """
9898  return is_fp(a) and _is_numeral(a.ctx, a.ast)
9899 
9900 
z3py.is_fp_value
def is_fp_value(a)
Definition: z3py.py:9886

◆ is_fprm()

def z3py.is_fprm (   a) 
Return `True` if `a` is a Z3 floating-point rounding mode expression.

>>> rm = RNE()
>>> is_fprm(rm)
True
>>> rm = 1.0
>>> is_fprm(rm)
False

Definition at line 9716 of file z3py.py.

9716 def is_fprm(a):
9717  """Return `True` if `a` is a Z3 floating-point rounding mode expression.
9718 
9719  >>> rm = RNE()
9720  >>> is_fprm(rm)
9721  True
9722  >>> rm = 1.0
9723  >>> is_fprm(rm)
9724  False
9725  """
9726  return isinstance(a, FPRMRef)
9727 
9728 

Referenced by fpFPToFP(), fpNeg(), fpRealToFP(), fpSignedToFP(), fpToFP(), fpToFPUnsigned(), fpToSBV(), fpToUBV(), fpUnsignedToFP(), and is_fprm_value().

◆ is_fprm_sort()

def z3py.is_fprm_sort (   s) 
Return True if `s` is a Z3 floating-point rounding mode sort.

>>> is_fprm_sort(FPSort(8, 24))
False
>>> is_fprm_sort(RNE().sort())
True

Definition at line 9467 of file z3py.py.

9467 def is_fprm_sort(s):
9468  """Return True if `s` is a Z3 floating-point rounding mode sort.
9469 
9470  >>> is_fprm_sort(FPSort(8, 24))
9471  False
9472  >>> is_fprm_sort(RNE().sort())
9473  True
9474  """
9475  return isinstance(s, FPRMSortRef)
9476 
9477 # FP Expressions
9478 
9479 
z3py.is_fprm_sort
def is_fprm_sort(s)
Definition: z3py.py:9467

◆ is_fprm_value()

def z3py.is_fprm_value (   a) 
Return `True` if `a` is a Z3 floating-point rounding mode numeral value.

Definition at line 9729 of file z3py.py.

9729 def is_fprm_value(a):
9730  """Return `True` if `a` is a Z3 floating-point rounding mode numeral value."""
9731  return is_fprm(a) and _is_numeral(a.ctx, a.ast)
9732 
9733 # FP Numerals
9734 
9735 
z3py.is_fprm_value
def is_fprm_value(a)
Definition: z3py.py:9729

Referenced by set_default_rounding_mode().

◆ is_func_decl()

def z3py.is_func_decl (   a) 
Return `True` if `a` is a Z3 function declaration.

>>> f = Function('f', IntSort(), IntSort())
>>> is_func_decl(f)
True
>>> x = Real('x')
>>> is_func_decl(x)
False

Definition at line 850 of file z3py.py.

850 def is_func_decl(a):
851  """Return `True` if `a` is a Z3 function declaration.
852 
853  >>> f = Function('f', IntSort(), IntSort())
854  >>> is_func_decl(f)
855  True
856  >>> x = Real('x')
857  >>> is_func_decl(x)
858  False
859  """
860  return isinstance(a, FuncDeclRef)
861 
862 
z3py.is_func_decl
def is_func_decl(a)
Definition: z3py.py:850

Referenced by Map(), prove(), substitute_funs(), and ModelRef.update_value().

◆ is_ge()

def z3py.is_ge (   a) 
Return `True` if `a` is an expression of the form b >= c.

>>> x, y = Ints('x y')
>>> is_ge(x >= y)
True
>>> is_ge(x == y)
False

Definition at line 2893 of file z3py.py.

2893 def is_ge(a):
2894  """Return `True` if `a` is an expression of the form b >= c.
2895 
2896  >>> x, y = Ints('x y')
2897  >>> is_ge(x >= y)
2898  True
2899  >>> is_ge(x == y)
2900  False
2901  """
2902  return is_app_of(a, Z3_OP_GE)
2903 
2904 
z3py.is_ge
def is_ge(a)
Definition: z3py.py:2893

◆ is_gt()

def z3py.is_gt (   a) 
Return `True` if `a` is an expression of the form b > c.

>>> x, y = Ints('x y')
>>> is_gt(x > y)
True
>>> is_gt(x == y)
False

Definition at line 2905 of file z3py.py.

2905 def is_gt(a):
2906  """Return `True` if `a` is an expression of the form b > c.
2907 
2908  >>> x, y = Ints('x y')
2909  >>> is_gt(x > y)
2910  True
2911  >>> is_gt(x == y)
2912  False
2913  """
2914  return is_app_of(a, Z3_OP_GT)
2915 
2916 
z3py.is_gt
def is_gt(a)
Definition: z3py.py:2905

◆ is_idiv()

def z3py.is_idiv (   a) 
Return `True` if `a` is an expression of the form b div c.

>>> x, y = Ints('x y')
>>> is_idiv(x / y)
True
>>> is_idiv(x + y)
False

Definition at line 2845 of file z3py.py.

2845 def is_idiv(a):
2846  """Return `True` if `a` is an expression of the form b div c.
2847 
2848  >>> x, y = Ints('x y')
2849  >>> is_idiv(x / y)
2850  True
2851  >>> is_idiv(x + y)
2852  False
2853  """
2854  return is_app_of(a, Z3_OP_IDIV)
2855 
2856 
z3py.is_idiv
def is_idiv(a)
Definition: z3py.py:2845

◆ is_implies()

def z3py.is_implies (   a) 
Return `True` if `a` is a Z3 implication expression.

>>> p, q = Bools('p q')
>>> is_implies(Implies(p, q))
True
>>> is_implies(And(p, q))
False

Definition at line 1645 of file z3py.py.

1645 def is_implies(a):
1646  """Return `True` if `a` is a Z3 implication expression.
1647 
1648  >>> p, q = Bools('p q')
1649  >>> is_implies(Implies(p, q))
1650  True
1651  >>> is_implies(And(p, q))
1652  False
1653  """
1654  return is_app_of(a, Z3_OP_IMPLIES)
1655 
1656 
z3py.is_implies
def is_implies(a)
Definition: z3py.py:1645

◆ is_int()

def z3py.is_int (   a) 
Return `True` if `a` is an integer expression.

>>> x = Int('x')
>>> is_int(x + 1)
True
>>> is_int(1)
False
>>> is_int(IntVal(1))
True
>>> y = Real('y')
>>> is_int(y)
False
>>> is_int(y + 1)
False

Definition at line 2686 of file z3py.py.

2686 def is_int(a):
2687  """Return `True` if `a` is an integer expression.
2688 
2689  >>> x = Int('x')
2690  >>> is_int(x + 1)
2691  True
2692  >>> is_int(1)
2693  False
2694  >>> is_int(IntVal(1))
2695  True
2696  >>> y = Real('y')
2697  >>> is_int(y)
2698  False
2699  >>> is_int(y + 1)
2700  False
2701  """
2702  return is_arith(a) and a.is_int()
2703 
2704 
z3py.is_int
def is_int(a)
Definition: z3py.py:2686

◆ is_int_value()

def z3py.is_int_value (   a) 
Return `True` if `a` is an integer value of sort Int.

>>> is_int_value(IntVal(1))
True
>>> is_int_value(1)
False
>>> is_int_value(Int('x'))
False
>>> n = Int('x') + 1
>>> n
x + 1
>>> n.arg(1)
1
>>> is_int_value(n.arg(1))
True
>>> is_int_value(RealVal("1/3"))
False
>>> is_int_value(RealVal(1))
False

Definition at line 2732 of file z3py.py.

2732 def is_int_value(a):
2733  """Return `True` if `a` is an integer value of sort Int.
2734 
2735  >>> is_int_value(IntVal(1))
2736  True
2737  >>> is_int_value(1)
2738  False
2739  >>> is_int_value(Int('x'))
2740  False
2741  >>> n = Int('x') + 1
2742  >>> n
2743  x + 1
2744  >>> n.arg(1)
2745  1
2746  >>> is_int_value(n.arg(1))
2747  True
2748  >>> is_int_value(RealVal("1/3"))
2749  False
2750  >>> is_int_value(RealVal(1))
2751  False
2752  """
2753  return is_arith(a) and a.is_int() and _is_numeral(a.ctx, a.as_ast())
2754 
2755 
z3py.is_int_value
def is_int_value(a)
Definition: z3py.py:2732

◆ is_is_int()

def z3py.is_is_int (   a) 
Return `True` if `a` is an expression of the form IsInt(b).

>>> x = Real('x')
>>> is_is_int(IsInt(x))
True
>>> is_is_int(x)
False

Definition at line 2917 of file z3py.py.

2917 def is_is_int(a):
2918  """Return `True` if `a` is an expression of the form IsInt(b).
2919 
2920  >>> x = Real('x')
2921  >>> is_is_int(IsInt(x))
2922  True
2923  >>> is_is_int(x)
2924  False
2925  """
2926  return is_app_of(a, Z3_OP_IS_INT)
2927 
2928 
z3py.is_is_int
def is_is_int(a)
Definition: z3py.py:2917

◆ is_K()

def z3py.is_K (   a) 
Return `True` if `a` is a Z3 constant array.

>>> a = K(IntSort(), 10)
>>> is_K(a)
True
>>> a = Array('a', IntSort(), IntSort())
>>> is_K(a)
False

Definition at line 4638 of file z3py.py.

4638 def is_K(a):
4639  """Return `True` if `a` is a Z3 constant array.
4640 
4641  >>> a = K(IntSort(), 10)
4642  >>> is_K(a)
4643  True
4644  >>> a = Array('a', IntSort(), IntSort())
4645  >>> is_K(a)
4646  False
4647  """
4648  return is_app_of(a, Z3_OP_CONST_ARRAY)
4649 
4650 
z3py.is_K
def is_K(a)
Definition: z3py.py:4638

◆ is_le()

def z3py.is_le (   a) 
Return `True` if `a` is an expression of the form b <= c.

>>> x, y = Ints('x y')
>>> is_le(x <= y)
True
>>> is_le(x < y)
False

Definition at line 2869 of file z3py.py.

2869 def is_le(a):
2870  """Return `True` if `a` is an expression of the form b <= c.
2871 
2872  >>> x, y = Ints('x y')
2873  >>> is_le(x <= y)
2874  True
2875  >>> is_le(x < y)
2876  False
2877  """
2878  return is_app_of(a, Z3_OP_LE)
2879 
2880 
z3py.is_le
def is_le(a)
Definition: z3py.py:2869

◆ is_lt()

def z3py.is_lt (   a) 
Return `True` if `a` is an expression of the form b < c.

>>> x, y = Ints('x y')
>>> is_lt(x < y)
True
>>> is_lt(x == y)
False

Definition at line 2881 of file z3py.py.

2881 def is_lt(a):
2882  """Return `True` if `a` is an expression of the form b < c.
2883 
2884  >>> x, y = Ints('x y')
2885  >>> is_lt(x < y)
2886  True
2887  >>> is_lt(x == y)
2888  False
2889  """
2890  return is_app_of(a, Z3_OP_LT)
2891 
2892 
z3py.is_lt
def is_lt(a)
Definition: z3py.py:2881

◆ is_map()

def z3py.is_map (   a) 
Return `True` if `a` is a Z3 map array expression.

>>> f = Function('f', IntSort(), IntSort())
>>> b = Array('b', IntSort(), IntSort())
>>> a  = Map(f, b)
>>> a
Map(f, b)
>>> is_map(a)
True
>>> is_map(b)
False

Definition at line 4651 of file z3py.py.

4651 def is_map(a):
4652  """Return `True` if `a` is a Z3 map array expression.
4653 
4654  >>> f = Function('f', IntSort(), IntSort())
4655  >>> b = Array('b', IntSort(), IntSort())
4656  >>> a = Map(f, b)
4657  >>> a
4658  Map(f, b)
4659  >>> is_map(a)
4660  True
4661  >>> is_map(b)
4662  False
4663  """
4664  return is_app_of(a, Z3_OP_ARRAY_MAP)
4665 
4666 

Referenced by get_map_func().

◆ is_mod()

def z3py.is_mod (   a) 
Return `True` if `a` is an expression of the form b % c.

>>> x, y = Ints('x y')
>>> is_mod(x % y)
True
>>> is_mod(x + y)
False

Definition at line 2857 of file z3py.py.

2857 def is_mod(a):
2858  """Return `True` if `a` is an expression of the form b % c.
2859 
2860  >>> x, y = Ints('x y')
2861  >>> is_mod(x % y)
2862  True
2863  >>> is_mod(x + y)
2864  False
2865  """
2866  return is_app_of(a, Z3_OP_MOD)
2867 
2868 
z3py.is_mod
def is_mod(a)
Definition: z3py.py:2857

◆ is_mul()

def z3py.is_mul (   a) 
Return `True` if `a` is an expression of the form b * c.

>>> x, y = Ints('x y')
>>> is_mul(x * y)
True
>>> is_mul(x - y)
False

Definition at line 2804 of file z3py.py.

2804 def is_mul(a):
2805  """Return `True` if `a` is an expression of the form b * c.
2806 
2807  >>> x, y = Ints('x y')
2808  >>> is_mul(x * y)
2809  True
2810  >>> is_mul(x - y)
2811  False
2812  """
2813  return is_app_of(a, Z3_OP_MUL)
2814 
2815 
z3py.is_mul
def is_mul(a)
Definition: z3py.py:2804

◆ is_not()

def z3py.is_not (   a) 
Return `True` if `a` is a Z3 not expression.

>>> p = Bool('p')
>>> is_not(p)
False
>>> is_not(Not(p))
True

Definition at line 1657 of file z3py.py.

1657 def is_not(a):
1658  """Return `True` if `a` is a Z3 not expression.
1659 
1660  >>> p = Bool('p')
1661  >>> is_not(p)
1662  False
1663  >>> is_not(Not(p))
1664  True
1665  """
1666  return is_app_of(a, Z3_OP_NOT)
1667 
1668 
z3py.is_not
def is_not(a)
Definition: z3py.py:1657

Referenced by mk_not().

◆ is_or()

def z3py.is_or (   a) 
Return `True` if `a` is a Z3 or expression.

>>> p, q = Bools('p q')
>>> is_or(Or(p, q))
True
>>> is_or(And(p, q))
False

Definition at line 1633 of file z3py.py.

1633 def is_or(a):
1634  """Return `True` if `a` is a Z3 or expression.
1635 
1636  >>> p, q = Bools('p q')
1637  >>> is_or(Or(p, q))
1638  True
1639  >>> is_or(And(p, q))
1640  False
1641  """
1642  return is_app_of(a, Z3_OP_OR)
1643 
1644 
z3py.is_or
def is_or(a)
Definition: z3py.py:1633

◆ is_pattern()

def z3py.is_pattern (   a) 
Return `True` if `a` is a Z3 pattern (hint for quantifier instantiation.

>>> f = Function('f', IntSort(), IntSort())
>>> x = Int('x')
>>> q = ForAll(x, f(x) == 0, patterns = [ f(x) ])
>>> q
ForAll(x, f(x) == 0)
>>> q.num_patterns()
1
>>> is_pattern(q.pattern(0))
True
>>> q.pattern(0)
f(Var(0))

Definition at line 1933 of file z3py.py.

1933 def is_pattern(a):
1934  """Return `True` if `a` is a Z3 pattern (hint for quantifier instantiation.
1935 
1936  >>> f = Function('f', IntSort(), IntSort())
1937  >>> x = Int('x')
1938  >>> q = ForAll(x, f(x) == 0, patterns = [ f(x) ])
1939  >>> q
1940  ForAll(x, f(x) == 0)
1941  >>> q.num_patterns()
1942  1
1943  >>> is_pattern(q.pattern(0))
1944  True
1945  >>> q.pattern(0)
1946  f(Var(0))
1947  """
1948  return isinstance(a, PatternRef)
1949 
1950 
z3py.is_pattern
def is_pattern(a)
Definition: z3py.py:1933

Referenced by is_quantifier(), and MultiPattern().

◆ is_probe()

def z3py.is_probe (   p) 
Return `True` if `p` is a Z3 probe.

>>> is_probe(Int('x'))
False
>>> is_probe(Probe('memory'))
True

Definition at line 8637 of file z3py.py.

8637 def is_probe(p):
8638  """Return `True` if `p` is a Z3 probe.
8639 
8640  >>> is_probe(Int('x'))
8641  False
8642  >>> is_probe(Probe('memory'))
8643  True
8644  """
8645  return isinstance(p, Probe)
8646 
8647 
z3py.is_probe
def is_probe(p)
Definition: z3py.py:8637

Referenced by eq(), mk_not(), and Not().

◆ is_quantifier()

def z3py.is_quantifier (   a) 
Return `True` if `a` is a Z3 quantifier.

>>> f = Function('f', IntSort(), IntSort())
>>> x = Int('x')
>>> q = ForAll(x, f(x) == 0)
>>> is_quantifier(q)
True
>>> is_quantifier(f(x))
False

Definition at line 2173 of file z3py.py.

2173 def is_quantifier(a):
2174  """Return `True` if `a` is a Z3 quantifier.
2175 
2176  >>> f = Function('f', IntSort(), IntSort())
2177  >>> x = Int('x')
2178  >>> q = ForAll(x, f(x) == 0)
2179  >>> is_quantifier(q)
2180  True
2181  >>> is_quantifier(f(x))
2182  False
2183  """
2184  return isinstance(a, QuantifierRef)
2185 
2186 
z3py.is_quantifier
def is_quantifier(a)
Definition: z3py.py:2173

◆ is_rational_value()

def z3py.is_rational_value (   a) 
Return `True` if `a` is rational value of sort Real.

>>> is_rational_value(RealVal(1))
True
>>> is_rational_value(RealVal("3/5"))
True
>>> is_rational_value(IntVal(1))
False
>>> is_rational_value(1)
False
>>> n = Real('x') + 1
>>> n.arg(1)
1
>>> is_rational_value(n.arg(1))
True
>>> is_rational_value(Real('x'))
False

Definition at line 2756 of file z3py.py.

2756 def is_rational_value(a):
2757  """Return `True` if `a` is rational value of sort Real.
2758 
2759  >>> is_rational_value(RealVal(1))
2760  True
2761  >>> is_rational_value(RealVal("3/5"))
2762  True
2763  >>> is_rational_value(IntVal(1))
2764  False
2765  >>> is_rational_value(1)
2766  False
2767  >>> n = Real('x') + 1
2768  >>> n.arg(1)
2769  1
2770  >>> is_rational_value(n.arg(1))
2771  True
2772  >>> is_rational_value(Real('x'))
2773  False
2774  """
2775  return is_arith(a) and a.is_real() and _is_numeral(a.ctx, a.as_ast())
2776 
2777 
z3py.is_rational_value
def is_rational_value(a)
Definition: z3py.py:2756

◆ is_re()

def z3py.is_re (   s)

Definition at line 11168 of file z3py.py.

11168 def is_re(s):
11169  return isinstance(s, ReRef)
11170 
11171 

Referenced by Concat(), Intersect(), and Union().

◆ is_real()

def z3py.is_real (   a) 
Return `True` if `a` is a real expression.

>>> x = Int('x')
>>> is_real(x + 1)
False
>>> y = Real('y')
>>> is_real(y)
True
>>> is_real(y + 1)
True
>>> is_real(1)
False
>>> is_real(RealVal(1))
True

Definition at line 2705 of file z3py.py.

2705 def is_real(a):
2706  """Return `True` if `a` is a real expression.
2707 
2708  >>> x = Int('x')
2709  >>> is_real(x + 1)
2710  False
2711  >>> y = Real('y')
2712  >>> is_real(y)
2713  True
2714  >>> is_real(y + 1)
2715  True
2716  >>> is_real(1)
2717  False
2718  >>> is_real(RealVal(1))
2719  True
2720  """
2721  return is_arith(a) and a.is_real()
2722 
2723 

Referenced by fpRealToFP(), and fpToFP().

◆ is_select()

def z3py.is_select (   a) 
Return `True` if `a` is a Z3 array select application.

>>> a = Array('a', IntSort(), IntSort())
>>> is_select(a)
False
>>> i = Int('i')
>>> is_select(a[i])
True

Definition at line 4886 of file z3py.py.

4886 def is_select(a):
4887  """Return `True` if `a` is a Z3 array select application.
4888 
4889  >>> a = Array('a', IntSort(), IntSort())
4890  >>> is_select(a)
4891  False
4892  >>> i = Int('i')
4893  >>> is_select(a[i])
4894  True
4895  """
4896  return is_app_of(a, Z3_OP_SELECT)
4897 
4898 
z3py.is_select
def is_select(a)
Definition: z3py.py:4886

◆ is_seq()

def z3py.is_seq (   a) 
Return `True` if `a` is a Z3 sequence expression.
>>> print (is_seq(Unit(IntVal(0))))
True
>>> print (is_seq(StringVal("abc")))
True

Definition at line 10894 of file z3py.py.

10894 def is_seq(a):
10895  """Return `True` if `a` is a Z3 sequence expression.
10896  >>> print (is_seq(Unit(IntVal(0))))
10897  True
10898  >>> print (is_seq(StringVal("abc")))
10899  True
10900  """
10901  return isinstance(a, SeqRef)
10902 
10903 

Referenced by CharIsDigit(), Concat(), and Extract().

◆ is_sort()

def z3py.is_sort (   s) 
Return `True` if `s` is a Z3 sort.

>>> is_sort(IntSort())
True
>>> is_sort(Int('x'))
False
>>> is_expr(Int('x'))
True

Definition at line 647 of file z3py.py.

647 def is_sort(s):
648  """Return `True` if `s` is a Z3 sort.
649 
650  >>> is_sort(IntSort())
651  True
652  >>> is_sort(Int('x'))
653  False
654  >>> is_expr(Int('x'))
655  True
656  """
657  return isinstance(s, SortRef)
658 
659 

Referenced by ArraySort(), CreateDatatypes(), FreshFunction(), Function(), IsSubset(), K(), PropagateFunction(), prove(), RecFunction(), and Var().

◆ is_store()

def z3py.is_store (   a) 
Return `True` if `a` is a Z3 array store application.

>>> a = Array('a', IntSort(), IntSort())
>>> is_store(a)
False
>>> is_store(Store(a, 0, 1))
True

Definition at line 4899 of file z3py.py.

4899 def is_store(a):
4900  """Return `True` if `a` is a Z3 array store application.
4901 
4902  >>> a = Array('a', IntSort(), IntSort())
4903  >>> is_store(a)
4904  False
4905  >>> is_store(Store(a, 0, 1))
4906  True
4907  """
4908  return is_app_of(a, Z3_OP_STORE)
4909 
z3py.is_store
def is_store(a)
Definition: z3py.py:4899

◆ is_string()

def z3py.is_string (   a) 
Return `True` if `a` is a Z3 string expression.
>>> print (is_string(StringVal("ab")))
True

Definition at line 10904 of file z3py.py.

10904 def is_string(a):
10905  """Return `True` if `a` is a Z3 string expression.
10906  >>> print (is_string(StringVal("ab")))
10907  True
10908  """
10909  return isinstance(a, SeqRef) and a.is_string()
10910 
10911 
z3py.is_string
def is_string(a)
Definition: z3py.py:10904

◆ is_string_value()

def z3py.is_string_value (   a) 
return 'True' if 'a' is a Z3 string constant expression.
>>> print (is_string_value(StringVal("a")))
True
>>> print (is_string_value(StringVal("a") + StringVal("b")))
False

Definition at line 10912 of file z3py.py.

10912 def is_string_value(a):
10913  """return 'True' if 'a' is a Z3 string constant expression.
10914  >>> print (is_string_value(StringVal("a")))
10915  True
10916  >>> print (is_string_value(StringVal("a") + StringVal("b")))
10917  False
10918  """
10919  return isinstance(a, SeqRef) and a.is_string_value()
10920 
z3py.is_string_value
def is_string_value(a)
Definition: z3py.py:10912

◆ is_sub()

def z3py.is_sub (   a) 
Return `True` if `a` is an expression of the form b - c.

>>> x, y = Ints('x y')
>>> is_sub(x - y)
True
>>> is_sub(x + y)
False

Definition at line 2816 of file z3py.py.

2816 def is_sub(a):
2817  """Return `True` if `a` is an expression of the form b - c.
2818 
2819  >>> x, y = Ints('x y')
2820  >>> is_sub(x - y)
2821  True
2822  >>> is_sub(x + y)
2823  False
2824  """
2825  return is_app_of(a, Z3_OP_SUB)
2826 
2827 
z3py.is_sub
def is_sub(a)
Definition: z3py.py:2816

◆ is_to_int()

def z3py.is_to_int (   a) 
Return `True` if `a` is an expression of the form ToInt(b).

>>> x = Real('x')
>>> n = ToInt(x)
>>> n
ToInt(x)
>>> is_to_int(n)
True
>>> is_to_int(x)
False

Definition at line 2944 of file z3py.py.

2944 def is_to_int(a):
2945  """Return `True` if `a` is an expression of the form ToInt(b).
2946 
2947  >>> x = Real('x')
2948  >>> n = ToInt(x)
2949  >>> n
2950  ToInt(x)
2951  >>> is_to_int(n)
2952  True
2953  >>> is_to_int(x)
2954  False
2955  """
2956  return is_app_of(a, Z3_OP_TO_INT)
2957 
2958 
z3py.is_to_int
def is_to_int(a)
Definition: z3py.py:2944

◆ is_to_real()

def z3py.is_to_real (   a) 
Return `True` if `a` is an expression of the form ToReal(b).

>>> x = Int('x')
>>> n = ToReal(x)
>>> n
ToReal(x)
>>> is_to_real(n)
True
>>> is_to_real(x)
False

Definition at line 2929 of file z3py.py.

2929 def is_to_real(a):
2930  """Return `True` if `a` is an expression of the form ToReal(b).
2931 
2932  >>> x = Int('x')
2933  >>> n = ToReal(x)
2934  >>> n
2935  ToReal(x)
2936  >>> is_to_real(n)
2937  True
2938  >>> is_to_real(x)
2939  False
2940  """
2941  return is_app_of(a, Z3_OP_TO_REAL)
2942 
2943 
z3py.is_to_real
def is_to_real(a)
Definition: z3py.py:2929

◆ is_true()

def z3py.is_true (   a) 
Return `True` if `a` is the Z3 true expression.

>>> p = Bool('p')
>>> is_true(p)
False
>>> is_true(simplify(p == p))
True
>>> x = Real('x')
>>> is_true(x == 0)
False
>>> # True is a Python Boolean expression
>>> is_true(True)
False

Definition at line 1589 of file z3py.py.

1589 def is_true(a):
1590  """Return `True` if `a` is the Z3 true expression.
1591 
1592  >>> p = Bool('p')
1593  >>> is_true(p)
1594  False
1595  >>> is_true(simplify(p == p))
1596  True
1597  >>> x = Real('x')
1598  >>> is_true(x == 0)
1599  False
1600  >>> # True is a Python Boolean expression
1601  >>> is_true(True)
1602  False
1603  """
1604  return is_app_of(a, Z3_OP_TRUE)
1605 
1606 
z3py.is_true
def is_true(a)
Definition: z3py.py:1589

Referenced by AstRef.__bool__().

◆ is_var()

def z3py.is_var (   a) 
Return `True` if `a` is variable.

Z3 uses de-Bruijn indices for representing bound variables in
quantifiers.

>>> x = Int('x')
>>> is_var(x)
False
>>> is_const(x)
True
>>> f = Function('f', IntSort(), IntSort())
>>> # Z3 replaces x with bound variables when ForAll is executed.
>>> q = ForAll(x, f(x) == x)
>>> b = q.body()
>>> b
f(Var(0)) == Var(0)
>>> b.arg(1)
Var(0)
>>> is_var(b.arg(1))
True

Definition at line 1310 of file z3py.py.

1310 def is_var(a):
1311  """Return `True` if `a` is variable.
1312 
1313  Z3 uses de-Bruijn indices for representing bound variables in
1314  quantifiers.
1315 
1316  >>> x = Int('x')
1317  >>> is_var(x)
1318  False
1319  >>> is_const(x)
1320  True
1321  >>> f = Function('f', IntSort(), IntSort())
1322  >>> # Z3 replaces x with bound variables when ForAll is executed.
1323  >>> q = ForAll(x, f(x) == x)
1324  >>> b = q.body()
1325  >>> b
1326  f(Var(0)) == Var(0)
1327  >>> b.arg(1)
1328  Var(0)
1329  >>> is_var(b.arg(1))
1330  True
1331  """
1332  return is_expr(a) and _ast_kind(a.ctx, a) == Z3_VAR_AST
1333 
1334 

Referenced by get_var_index().

◆ IsInt()

def z3py.IsInt (   a) 
 Return the Z3 predicate IsInt(a).

>>> x = Real('x')
>>> IsInt(x + "1/2")
IsInt(x + 1/2)
>>> solve(IsInt(x + "1/2"), x > 0, x < 1)
[x = 1/2]
>>> solve(IsInt(x + "1/2"), x > 0, x < 1, x != "1/2")
no solution

Definition at line 3394 of file z3py.py.

3394 def IsInt(a):
3395  """ Return the Z3 predicate IsInt(a).
3396 
3397  >>> x = Real('x')
3398  >>> IsInt(x + "1/2")
3399  IsInt(x + 1/2)
3400  >>> solve(IsInt(x + "1/2"), x > 0, x < 1)
3401  [x = 1/2]
3402  >>> solve(IsInt(x + "1/2"), x > 0, x < 1, x != "1/2")
3403  no solution
3404  """
3405  if z3_debug():
3406  _z3_assert(a.is_real(), "Z3 real expression expected.")
3407  ctx = a.ctx
3408  return BoolRef(Z3_mk_is_int(ctx.ref(), a.as_ast()), ctx)
3409 
3410 
Z3_mk_is_int
Z3_ast Z3_API Z3_mk_is_int(Z3_context c, Z3_ast t1)
Check if a real number is an integer.
z3py.IsInt
def IsInt(a)
Definition: z3py.py:3394

◆ IsMember()

def z3py.IsMember (   e,
  s 
) 
 Check if e is a member of set s
>>> a = Const('a', SetSort(IntSort()))
>>> IsMember(1, a)
a[1]

Definition at line 5009 of file z3py.py.

5009 def IsMember(e, s):
5010  """ Check if e is a member of set s
5011  >>> a = Const('a', SetSort(IntSort()))
5012  >>> IsMember(1, a)
5013  a[1]
5014  """
5015  ctx = _ctx_from_ast_arg_list([s, e])
5016  e = _py2expr(e, ctx)
5017  return BoolRef(Z3_mk_set_member(ctx.ref(), e.as_ast(), s.as_ast()), ctx)
5018 
5019 
Z3_mk_set_member
Z3_ast Z3_API Z3_mk_set_member(Z3_context c, Z3_ast elem, Z3_ast set)
Check for set membership.
z3py.IsMember
def IsMember(e, s)
Definition: z3py.py:5009

◆ IsSubset()

def z3py.IsSubset (   a,
  b 
) 
 Check if a is a subset of b
>>> a = Const('a', SetSort(IntSort()))
>>> b = Const('b', SetSort(IntSort()))
>>> IsSubset(a, b)
subset(a, b)

Definition at line 5020 of file z3py.py.

5020 def IsSubset(a, b):
5021  """ Check if a is a subset of b
5022  >>> a = Const('a', SetSort(IntSort()))
5023  >>> b = Const('b', SetSort(IntSort()))
5024  >>> IsSubset(a, b)
5025  subset(a, b)
5026  """
5027  ctx = _ctx_from_ast_arg_list([a, b])
5028  return BoolRef(Z3_mk_set_subset(ctx.ref(), a.as_ast(), b.as_ast()), ctx)
5029 
5030 
Z3_mk_set_subset
Z3_ast Z3_API Z3_mk_set_subset(Z3_context c, Z3_ast arg1, Z3_ast arg2)
Check for subsetness of sets.
z3py.IsSubset
def IsSubset(a, b)
Definition: z3py.py:5020

◆ K()

def z3py.K (   dom,
  v 
) 
Return a Z3 constant array expression.

>>> a = K(IntSort(), 10)
>>> a
K(Int, 10)
>>> a.sort()
Array(Int, Int)
>>> i = Int('i')
>>> a[i]
K(Int, 10)[i]
>>> simplify(a[i])
10

Definition at line 4846 of file z3py.py.

4846 def K(dom, v):
4847  """Return a Z3 constant array expression.
4848 
4849  >>> a = K(IntSort(), 10)
4850  >>> a
4851  K(Int, 10)
4852  >>> a.sort()
4853  Array(Int, Int)
4854  >>> i = Int('i')
4855  >>> a[i]
4856  K(Int, 10)[i]
4857  >>> simplify(a[i])
4858  10
4859  """
4860  if z3_debug():
4861  _z3_assert(is_sort(dom), "Z3 sort expected")
4862  ctx = dom.ctx
4863  if not is_expr(v):
4864  v = _py2expr(v, ctx)
4865  return ArrayRef(Z3_mk_const_array(ctx.ref(), dom.ast, v.as_ast()), ctx)
4866 
4867 
Z3_mk_const_array
Z3_ast Z3_API Z3_mk_const_array(Z3_context c, Z3_sort domain, Z3_ast v)
Create the constant array.
z3py.K
def K(dom, v)
Definition: z3py.py:4846

Referenced by ModelRef.get_interp().

◆ Lambda()

def z3py.Lambda (   vs,
  body 
) 
Create a Z3 lambda expression.

>>> f = Function('f', IntSort(), IntSort(), IntSort())
>>> mem0 = Array('mem0', IntSort(), IntSort())
>>> lo, hi, e, i = Ints('lo hi e i')
>>> mem1 = Lambda([i], If(And(lo <= i, i <= hi), e, mem0[i]))
>>> mem1
Lambda(i, If(And(lo <= i, i <= hi), e, mem0[i]))

Definition at line 2261 of file z3py.py.

2261 def Lambda(vs, body):
2262  """Create a Z3 lambda expression.
2263 
2264  >>> f = Function('f', IntSort(), IntSort(), IntSort())
2265  >>> mem0 = Array('mem0', IntSort(), IntSort())
2266  >>> lo, hi, e, i = Ints('lo hi e i')
2267  >>> mem1 = Lambda([i], If(And(lo <= i, i <= hi), e, mem0[i]))
2268  >>> mem1
2269  Lambda(i, If(And(lo <= i, i <= hi), e, mem0[i]))
2270  """
2271  ctx = body.ctx
2272  if is_app(vs):
2273  vs = [vs]
2274  num_vars = len(vs)
2275  _vs = (Ast * num_vars)()
2276  for i in range(num_vars):
2277  # TODO: Check if is constant
2278  _vs[i] = vs[i].as_ast()
2279  return QuantifierRef(Z3_mk_lambda_const(ctx.ref(), num_vars, _vs, body.as_ast()), ctx)
2280 
Z3_mk_lambda_const
Z3_ast Z3_API Z3_mk_lambda_const(Z3_context c, unsigned num_bound, Z3_app const bound[], Z3_ast body)
Create a lambda expression using a list of constants that form the set of bound variables.
z3py.Lambda
def Lambda(vs, body)
Definition: z3py.py:2261

Referenced by Context.MkLambda().

◆ LastIndexOf()

def z3py.LastIndexOf (   s,
  substr 
) 
Retrieve the last index of substring within a string

Definition at line 11079 of file z3py.py.

11079 def LastIndexOf(s, substr):
11080  """Retrieve the last index of substring within a string"""
11081  ctx = None
11082  ctx = _get_ctx2(s, substr, ctx)
11083  s = _coerce_seq(s, ctx)
11084  substr = _coerce_seq(substr, ctx)
11085  return ArithRef(Z3_mk_seq_last_index(s.ctx_ref(), s.as_ast(), substr.as_ast()), s.ctx)
11086 
11087 
Z3_mk_seq_last_index
Z3_ast Z3_API Z3_mk_seq_last_index(Z3_context c, Z3_ast s, Z3_ast substr)
Return index of the last occurrence of substr in s. If s does not contain substr, then the value is -...
z3py.LastIndexOf
def LastIndexOf(s, substr)
Definition: z3py.py:11079

◆ Length()

def z3py.Length (   s) 
Obtain the length of a sequence 's'
>>> l = Length(StringVal("abc"))
>>> simplify(l)
3

Definition at line 11088 of file z3py.py.

11088 def Length(s):
11089  """Obtain the length of a sequence 's'
11090  >>> l = Length(StringVal("abc"))
11091  >>> simplify(l)
11092  3
11093  """
11094  s = _coerce_seq(s)
11095  return ArithRef(Z3_mk_seq_length(s.ctx_ref(), s.as_ast()), s.ctx)
11096 
11097 
Z3_mk_seq_length
Z3_ast Z3_API Z3_mk_seq_length(Z3_context c, Z3_ast s)
Return the length of the sequence s.
z3py.Length
def Length(s)
Definition: z3py.py:11088

Referenced by NativeContext.MkAdd(), NativeContext.MkAnd(), NativeContext.MkApp(), NativeContext.MkFreshFuncDecl(), NativeContext.MkFuncDecl(), NativeContext.MkMul(), NativeContext.MkOr(), NativeContext.MkSub(), and NativeContext.MkTupleSort().

◆ LinearOrder()

def z3py.LinearOrder (   a,
  index 
)

Definition at line 11310 of file z3py.py.

11310 def LinearOrder(a, index):
11311  return FuncDeclRef(Z3_mk_linear_order(a.ctx_ref(), a.ast, index), a.ctx)
11312 
11313 
Z3_mk_linear_order
Z3_func_decl Z3_API Z3_mk_linear_order(Z3_context c, Z3_sort a, unsigned id)
create a linear ordering relation over signature a. The relation is identified by the index id.
z3py.LinearOrder
def LinearOrder(a, index)
Definition: z3py.py:11310

◆ Loop()

def z3py.Loop (   re,
  lo,
  hi = 0 
) 
Create the regular expression accepting between a lower and upper bound repetitions
>>> re = Loop(Re("a"), 1, 3)
>>> print(simplify(InRe("aa", re)))
True
>>> print(simplify(InRe("aaaa", re)))
False
>>> print(simplify(InRe("", re)))
False

Definition at line 11268 of file z3py.py.

11268 def Loop(re, lo, hi=0):
11269  """Create the regular expression accepting between a lower and upper bound repetitions
11270  >>> re = Loop(Re("a"), 1, 3)
11271  >>> print(simplify(InRe("aa", re)))
11272  True
11273  >>> print(simplify(InRe("aaaa", re)))
11274  False
11275  >>> print(simplify(InRe("", re)))
11276  False
11277  """
11278  return ReRef(Z3_mk_re_loop(re.ctx_ref(), re.as_ast(), lo, hi), re.ctx)
11279 
11280 
Z3_mk_re_loop
Z3_ast Z3_API Z3_mk_re_loop(Z3_context c, Z3_ast r, unsigned lo, unsigned hi)
Create a regular expression loop. The supplied regular expression r is repeated between lo and hi tim...
z3py.Loop
def Loop(re, lo, hi=0)
Definition: z3py.py:11268

◆ LShR()

def z3py.LShR (   a,
  b 
) 
Create the Z3 expression logical right shift.

Use the operator >> for the arithmetical right shift.

>>> x, y = BitVecs('x y', 32)
>>> LShR(x, y)
LShR(x, y)
>>> (x >> y).sexpr()
'(bvashr x y)'
>>> LShR(x, y).sexpr()
'(bvlshr x y)'
>>> BitVecVal(4, 3)
4
>>> BitVecVal(4, 3).as_signed_long()
-4
>>> simplify(BitVecVal(4, 3) >> 1).as_signed_long()
-2
>>> simplify(BitVecVal(4, 3) >> 1)
6
>>> simplify(LShR(BitVecVal(4, 3), 1))
2
>>> simplify(BitVecVal(2, 3) >> 1)
1
>>> simplify(LShR(BitVecVal(2, 3), 1))
1

Definition at line 4299 of file z3py.py.

4299 def LShR(a, b):
4300  """Create the Z3 expression logical right shift.
4301 
4302  Use the operator >> for the arithmetical right shift.
4303 
4304  >>> x, y = BitVecs('x y', 32)
4305  >>> LShR(x, y)
4306  LShR(x, y)
4307  >>> (x >> y).sexpr()
4308  '(bvashr x y)'
4309  >>> LShR(x, y).sexpr()
4310  '(bvlshr x y)'
4311  >>> BitVecVal(4, 3)
4312  4
4313  >>> BitVecVal(4, 3).as_signed_long()
4314  -4
4315  >>> simplify(BitVecVal(4, 3) >> 1).as_signed_long()
4316  -2
4317  >>> simplify(BitVecVal(4, 3) >> 1)
4318  6
4319  >>> simplify(LShR(BitVecVal(4, 3), 1))
4320  2
4321  >>> simplify(BitVecVal(2, 3) >> 1)
4322  1
4323  >>> simplify(LShR(BitVecVal(2, 3), 1))
4324  1
4325  """
4326  _check_bv_args(a, b)
4327  a, b = _coerce_exprs(a, b)
4328  return BitVecRef(Z3_mk_bvlshr(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4329 
4330 
Z3_mk_bvlshr
Z3_ast Z3_API Z3_mk_bvlshr(Z3_context c, Z3_ast t1, Z3_ast t2)
Logical shift right.
z3py.LShR
def LShR(a, b)
Definition: z3py.py:4299

◆ main_ctx()

def z3py.main_ctx ( ) 
Return a reference to the global Z3 context.

>>> x = Real('x')
>>> x.ctx == main_ctx()
True
>>> c = Context()
>>> c == main_ctx()
False
>>> x2 = Real('x', c)
>>> x2.ctx == c
True
>>> eq(x, x2)
False

Definition at line 239 of file z3py.py.

239 def main_ctx():
240  """Return a reference to the global Z3 context.
241 
242  >>> x = Real('x')
243  >>> x.ctx == main_ctx()
244  True
245  >>> c = Context()
246  >>> c == main_ctx()
247  False
248  >>> x2 = Real('x', c)
249  >>> x2.ctx == c
250  True
251  >>> eq(x, x2)
252  False
253  """
254  global _main_ctx
255  if _main_ctx is None:
256  _main_ctx = Context()
257  return _main_ctx
258 
259 

Referenced by CharIsDigit(), help_simplify(), and simplify_param_descrs().

◆ Map()

def z3py.Map (   f,
args 
) 
Return a Z3 map array expression.

>>> f = Function('f', IntSort(), IntSort(), IntSort())
>>> a1 = Array('a1', IntSort(), IntSort())
>>> a2 = Array('a2', IntSort(), IntSort())
>>> b  = Map(f, a1, a2)
>>> b
Map(f, a1, a2)
>>> prove(b[0] == f(a1[0], a2[0]))
proved

Definition at line 4823 of file z3py.py.

4823 def Map(f, *args):
4824  """Return a Z3 map array expression.
4825 
4826  >>> f = Function('f', IntSort(), IntSort(), IntSort())
4827  >>> a1 = Array('a1', IntSort(), IntSort())
4828  >>> a2 = Array('a2', IntSort(), IntSort())
4829  >>> b = Map(f, a1, a2)
4830  >>> b
4831  Map(f, a1, a2)
4832  >>> prove(b[0] == f(a1[0], a2[0]))
4833  proved
4834  """
4835  args = _get_args(args)
4836  if z3_debug():
4837  _z3_assert(len(args) > 0, "At least one Z3 array expression expected")
4838  _z3_assert(is_func_decl(f), "First argument must be a Z3 function declaration")
4839  _z3_assert(all([is_array(a) for a in args]), "Z3 array expected expected")
4840  _z3_assert(len(args) == f.arity(), "Number of arguments mismatch")
4841  _args, sz = _to_ast_array(args)
4842  ctx = f.ctx
4843  return ArrayRef(Z3_mk_map(ctx.ref(), f.ast, sz, _args), ctx)
4844 
4845 
Z3_mk_map
Z3_ast Z3_API Z3_mk_map(Z3_context c, Z3_func_decl f, unsigned n, Z3_ast const *args)
Map f on the argument arrays.
z3py.Map
def Map(f, *args)
Definition: z3py.py:4823

Referenced by Context.Context().

◆ mk_not()

def z3py.mk_not (   a)

Definition at line 1834 of file z3py.py.

1834 def mk_not(a):
1835  if is_not(a):
1836  return a.arg(0)
1837  else:
1838  return Not(a)
1839 
1840 
z3py.mk_not
def mk_not(a)
Definition: z3py.py:1834

◆ Model()

def z3py.Model (   ctx = None)

Definition at line 6689 of file z3py.py.

6689 def Model(ctx=None):
6690  ctx = _get_ctx(ctx)
6691  return ModelRef(Z3_mk_model(ctx.ref()), ctx)
6692 
6693 
Z3_mk_model
Z3_model Z3_API Z3_mk_model(Z3_context c)
Create a fresh model object. It has reference count 0.
z3py.Model
def Model(ctx=None)
Definition: z3py.py:6689

Referenced by Goal.ConvertModel(), Goal.convertModel(), Optimize.getModel(), Solver.getModel(), and Optimize.set_on_model().

◆ MultiPattern()

def z3py.MultiPattern ( args) 
Create a Z3 multi-pattern using the given expressions `*args`

>>> f = Function('f', IntSort(), IntSort())
>>> g = Function('g', IntSort(), IntSort())
>>> x = Int('x')
>>> q = ForAll(x, f(x) != g(x), patterns = [ MultiPattern(f(x), g(x)) ])
>>> q
ForAll(x, f(x) != g(x))
>>> q.num_patterns()
1
>>> is_pattern(q.pattern(0))
True
>>> q.pattern(0)
MultiPattern(f(Var(0)), g(Var(0)))

Definition at line 1951 of file z3py.py.

1951 def MultiPattern(*args):
1952  """Create a Z3 multi-pattern using the given expressions `*args`
1953 
1954  >>> f = Function('f', IntSort(), IntSort())
1955  >>> g = Function('g', IntSort(), IntSort())
1956  >>> x = Int('x')
1957  >>> q = ForAll(x, f(x) != g(x), patterns = [ MultiPattern(f(x), g(x)) ])
1958  >>> q
1959  ForAll(x, f(x) != g(x))
1960  >>> q.num_patterns()
1961  1
1962  >>> is_pattern(q.pattern(0))
1963  True
1964  >>> q.pattern(0)
1965  MultiPattern(f(Var(0)), g(Var(0)))
1966  """
1967  if z3_debug():
1968  _z3_assert(len(args) > 0, "At least one argument expected")
1969  _z3_assert(all([is_expr(a) for a in args]), "Z3 expressions expected")
1970  ctx = args[0].ctx
1971  args, sz = _to_ast_array(args)
1972  return PatternRef(Z3_mk_pattern(ctx.ref(), sz, args), ctx)
1973 
1974 
Z3_mk_pattern
Z3_pattern Z3_API Z3_mk_pattern(Z3_context c, unsigned num_patterns, Z3_ast const terms[])
Create a pattern for quantifier instantiation.
z3py.MultiPattern
def MultiPattern(*args)
Definition: z3py.py:1951

◆ Not()

def z3py.Not (   a,
  ctx = None 
) 
Create a Z3 not expression or probe.

>>> p = Bool('p')
>>> Not(Not(p))
Not(Not(p))
>>> simplify(Not(Not(p)))
p

Definition at line 1815 of file z3py.py.

1815 def Not(a, ctx=None):
1816  """Create a Z3 not expression or probe.
1817 
1818  >>> p = Bool('p')
1819  >>> Not(Not(p))
1820  Not(Not(p))
1821  >>> simplify(Not(Not(p)))
1822  p
1823  """
1824  ctx = _get_ctx(_ctx_from_ast_arg_list([a], ctx))
1825  if is_probe(a):
1826  # Not is also used to build probes
1827  return Probe(Z3_probe_not(ctx.ref(), a.probe), ctx)
1828  else:
1829  s = BoolSort(ctx)
1830  a = s.cast(a)
1831  return BoolRef(Z3_mk_not(ctx.ref(), a.as_ast()), ctx)
1832 
1833 
Z3_probe_not
Z3_probe Z3_API Z3_probe_not(Z3_context x, Z3_probe p)
Return a probe that evaluates to "true" when p does not evaluate to true.
Z3_mk_not
Z3_ast Z3_API Z3_mk_not(Z3_context c, Z3_ast a)
Create an AST node representing not(a).

Referenced by fpNEQ(), mk_not(), and prove().

◆ on_clause_eh()

def z3py.on_clause_eh (   ctx,
  p,
  clause 
)

Definition at line 11350 of file z3py.py.

11350 def on_clause_eh(ctx, p, clause):
11351  onc = _my_hacky_class
11352  p = _to_expr_ref(to_Ast(p), onc.ctx)
11353  clause = AstVector(to_AstVectorObj(clause), onc.ctx)
11354  onc.on_clause(p, clause)
11355 
z3py.on_clause_eh
def on_clause_eh(ctx, p, clause)
Definition: z3py.py:11350
z3py.to_AstVectorObj
def to_AstVectorObj(ptr)
Definition: z3py.py:11339
z3py.to_Ast
def to_Ast(ptr)
Definition: z3py.py:11329

Referenced by on_clause.on_clause().

◆ open_log()

def z3py.open_log (   fname) 
Log interaction to a file. This function must be invoked immediately after init().

Definition at line 114 of file z3py.py.

114 def open_log(fname):
115  """Log interaction to a file. This function must be invoked immediately after init(). """
116  Z3_open_log(fname)
117 
118 
Z3_open_log
bool Z3_API Z3_open_log(Z3_string filename)
Log interaction to a file.
z3py.open_log
def open_log(fname)
Definition: z3py.py:114

◆ Option()

def z3py.Option (   re) 
Create the regular expression that optionally accepts the argument.
>>> re = Option(Re("a"))
>>> print(simplify(InRe("a", re)))
True
>>> print(simplify(InRe("", re)))
True
>>> print(simplify(InRe("aa", re)))
False

Definition at line 11237 of file z3py.py.

11237 def Option(re):
11238  """Create the regular expression that optionally accepts the argument.
11239  >>> re = Option(Re("a"))
11240  >>> print(simplify(InRe("a", re)))
11241  True
11242  >>> print(simplify(InRe("", re)))
11243  True
11244  >>> print(simplify(InRe("aa", re)))
11245  False
11246  """
11247  return ReRef(Z3_mk_re_option(re.ctx_ref(), re.as_ast()), re.ctx)
11248 
11249 
Z3_mk_re_option
Z3_ast Z3_API Z3_mk_re_option(Z3_context c, Z3_ast re)
Create the regular language [re].
z3py.Option
def Option(re)
Definition: z3py.py:11237

◆ Or()

def z3py.Or ( args) 
Create a Z3 or-expression or or-probe.

>>> p, q, r = Bools('p q r')
>>> Or(p, q, r)
Or(p, q, r)
>>> P = BoolVector('p', 5)
>>> Or(P)
Or(p__0, p__1, p__2, p__3, p__4)

Definition at line 1882 of file z3py.py.

1882 def Or(*args):
1883  """Create a Z3 or-expression or or-probe.
1884 
1885  >>> p, q, r = Bools('p q r')
1886  >>> Or(p, q, r)
1887  Or(p, q, r)
1888  >>> P = BoolVector('p', 5)
1889  >>> Or(P)
1890  Or(p__0, p__1, p__2, p__3, p__4)
1891  """
1892  last_arg = None
1893  if len(args) > 0:
1894  last_arg = args[len(args) - 1]
1895  if isinstance(last_arg, Context):
1896  ctx = args[len(args) - 1]
1897  args = args[:len(args) - 1]
1898  elif len(args) == 1 and isinstance(args[0], AstVector):
1899  ctx = args[0].ctx
1900  args = [a for a in args[0]]
1901  else:
1902  ctx = None
1903  args = _get_args(args)
1904  ctx = _get_ctx(_ctx_from_ast_arg_list(args, ctx))
1905  if z3_debug():
1906  _z3_assert(ctx is not None, "At least one of the arguments must be a Z3 expression or probe")
1907  if _has_probe(args):
1908  return _probe_or(args, ctx)
1909  else:
1910  args = _coerce_expr_list(args, ctx)
1911  _args, sz = _to_ast_array(args)
1912  return BoolRef(Z3_mk_or(ctx.ref(), sz, _args), ctx)
1913 
Z3_mk_or
Z3_ast Z3_API Z3_mk_or(Z3_context c, unsigned num_args, Z3_ast const args[])
Create an AST node representing args[0] or ... or args[num_args-1].
z3py.Or
def Or(*args)
Definition: z3py.py:1882

Referenced by ApplyResult.as_expr().

◆ OrElse()

def z3py.OrElse ( ts,
**  ks 
) 
Return a tactic that applies the tactics in `*ts` until one of them succeeds (it doesn't fail).

>>> x = Int('x')
>>> t = OrElse(Tactic('split-clause'), Tactic('skip'))
>>> # Tactic split-clause fails if there is no clause in the given goal.
>>> t(x == 0)
[[x == 0]]
>>> t(Or(x == 0, x == 1))
[[x == 0], [x == 1]]

Definition at line 8330 of file z3py.py.

8330 def OrElse(*ts, **ks):
8331  """Return a tactic that applies the tactics in `*ts` until one of them succeeds (it doesn't fail).
8332 
8333  >>> x = Int('x')
8334  >>> t = OrElse(Tactic('split-clause'), Tactic('skip'))
8335  >>> # Tactic split-clause fails if there is no clause in the given goal.
8336  >>> t(x == 0)
8337  [[x == 0]]
8338  >>> t(Or(x == 0, x == 1))
8339  [[x == 0], [x == 1]]
8340  """
8341  if z3_debug():
8342  _z3_assert(len(ts) >= 2, "At least two arguments expected")
8343  ctx = ks.get("ctx", None)
8344  num = len(ts)
8345  r = ts[0]
8346  for i in range(num - 1):
8347  r = _or_else(r, ts[i + 1], ctx)
8348  return r
8349 
8350 
z3py.OrElse
def OrElse(*ts, **ks)
Definition: z3py.py:8330

◆ ParAndThen()

def z3py.ParAndThen (   t1,
  t2,
  ctx = None 
) 
Alias for ParThen(t1, t2, ctx).

Definition at line 8386 of file z3py.py.

8386 def ParAndThen(t1, t2, ctx=None):
8387  """Alias for ParThen(t1, t2, ctx)."""
8388  return ParThen(t1, t2, ctx)
8389 
8390 
z3py.ParThen
def ParThen(t1, t2, ctx=None)
Definition: z3py.py:8370
z3py.ParAndThen
def ParAndThen(t1, t2, ctx=None)
Definition: z3py.py:8386

◆ ParOr()

def z3py.ParOr ( ts,
**  ks 
) 
Return a tactic that applies the tactics in `*ts` in parallel until one of them succeeds (it doesn't fail).

>>> x = Int('x')
>>> t = ParOr(Tactic('simplify'), Tactic('fail'))
>>> t(x + 1 == 2)
[[x == 1]]

Definition at line 8351 of file z3py.py.

8351 def ParOr(*ts, **ks):
8352  """Return a tactic that applies the tactics in `*ts` in parallel until one of them succeeds (it doesn't fail).
8353 
8354  >>> x = Int('x')
8355  >>> t = ParOr(Tactic('simplify'), Tactic('fail'))
8356  >>> t(x + 1 == 2)
8357  [[x == 1]]
8358  """
8359  if z3_debug():
8360  _z3_assert(len(ts) >= 2, "At least two arguments expected")
8361  ctx = _get_ctx(ks.get("ctx", None))
8362  ts = [_to_tactic(t, ctx) for t in ts]
8363  sz = len(ts)
8364  _args = (TacticObj * sz)()
8365  for i in range(sz):
8366  _args[i] = ts[i].tactic
8367  return Tactic(Z3_tactic_par_or(ctx.ref(), sz, _args), ctx)
8368 
8369 
Z3_tactic_par_or
Z3_tactic Z3_API Z3_tactic_par_or(Z3_context c, unsigned num, Z3_tactic const ts[])
Return a tactic that applies the given tactics in parallel.
z3py.ParOr
def ParOr(*ts, **ks)
Definition: z3py.py:8351

◆ parse_smt2_file()

def z3py.parse_smt2_file (   f,
  sorts = {},
  decls = {},
  ctx = None 
) 
Parse a file in SMT 2.0 format using the given sorts and decls.

This function is similar to parse_smt2_string().

Definition at line 9266 of file z3py.py.

9266 def parse_smt2_file(f, sorts={}, decls={}, ctx=None):
9267  """Parse a file in SMT 2.0 format using the given sorts and decls.
9268 
9269  This function is similar to parse_smt2_string().
9270  """
9271  ctx = _get_ctx(ctx)
9272  ssz, snames, ssorts = _dict2sarray(sorts, ctx)
9273  dsz, dnames, ddecls = _dict2darray(decls, ctx)
9274  return AstVector(Z3_parse_smtlib2_file(ctx.ref(), f, ssz, snames, ssorts, dsz, dnames, ddecls), ctx)
9275 
9276 
Z3_parse_smtlib2_file
Z3_ast_vector Z3_API Z3_parse_smtlib2_file(Z3_context c, Z3_string file_name, unsigned num_sorts, Z3_symbol const sort_names[], Z3_sort const sorts[], unsigned num_decls, Z3_symbol const decl_names[], Z3_func_decl const decls[])
Similar to Z3_parse_smtlib2_string, but reads the benchmark from a file.
z3py.parse_smt2_file
def parse_smt2_file(f, sorts={}, decls={}, ctx=None)
Definition: z3py.py:9266

◆ parse_smt2_string()

def z3py.parse_smt2_string (   s,
  sorts = {},
  decls = {},
  ctx = None 
) 
Parse a string in SMT 2.0 format using the given sorts and decls.

The arguments sorts and decls are Python dictionaries used to initialize
the symbol table used for the SMT 2.0 parser.

>>> parse_smt2_string('(declare-const x Int) (assert (> x 0)) (assert (< x 10))')
[x > 0, x < 10]
>>> x, y = Ints('x y')
>>> f = Function('f', IntSort(), IntSort())
>>> parse_smt2_string('(assert (> (+ foo (g bar)) 0))', decls={ 'foo' : x, 'bar' : y, 'g' : f})
[x + f(y) > 0]
>>> parse_smt2_string('(declare-const a U) (assert (> a 0))', sorts={ 'U' : IntSort() })
[a > 0]

Definition at line 9245 of file z3py.py.

9245 def parse_smt2_string(s, sorts={}, decls={}, ctx=None):
9246  """Parse a string in SMT 2.0 format using the given sorts and decls.
9247 
9248  The arguments sorts and decls are Python dictionaries used to initialize
9249  the symbol table used for the SMT 2.0 parser.
9250 
9251  >>> parse_smt2_string('(declare-const x Int) (assert (> x 0)) (assert (< x 10))')
9252  [x > 0, x < 10]
9253  >>> x, y = Ints('x y')
9254  >>> f = Function('f', IntSort(), IntSort())
9255  >>> parse_smt2_string('(assert (> (+ foo (g bar)) 0))', decls={ 'foo' : x, 'bar' : y, 'g' : f})
9256  [x + f(y) > 0]
9257  >>> parse_smt2_string('(declare-const a U) (assert (> a 0))', sorts={ 'U' : IntSort() })
9258  [a > 0]
9259  """
9260  ctx = _get_ctx(ctx)
9261  ssz, snames, ssorts = _dict2sarray(sorts, ctx)
9262  dsz, dnames, ddecls = _dict2darray(decls, ctx)
9263  return AstVector(Z3_parse_smtlib2_string(ctx.ref(), s, ssz, snames, ssorts, dsz, dnames, ddecls), ctx)
9264 
9265 
Z3_parse_smtlib2_string
Z3_ast_vector Z3_API Z3_parse_smtlib2_string(Z3_context c, Z3_string str, unsigned num_sorts, Z3_symbol const sort_names[], Z3_sort const sorts[], unsigned num_decls, Z3_symbol const decl_names[], Z3_func_decl const decls[])
Parse the given string using the SMT-LIB2 parser.
z3py.parse_smt2_string
def parse_smt2_string(s, sorts={}, decls={}, ctx=None)
Definition: z3py.py:9245

◆ ParThen()

def z3py.ParThen (   t1,
  t2,
  ctx = None 
) 
Return a tactic that applies t1 and then t2 to every subgoal produced by t1.
The subgoals are processed in parallel.

>>> x, y = Ints('x y')
>>> t = ParThen(Tactic('split-clause'), Tactic('propagate-values'))
>>> t(And(Or(x == 1, x == 2), y == x + 1))
[[x == 1, y == 2], [x == 2, y == 3]]

Definition at line 8370 of file z3py.py.

8370 def ParThen(t1, t2, ctx=None):
8371  """Return a tactic that applies t1 and then t2 to every subgoal produced by t1.
8372  The subgoals are processed in parallel.
8373 
8374  >>> x, y = Ints('x y')
8375  >>> t = ParThen(Tactic('split-clause'), Tactic('propagate-values'))
8376  >>> t(And(Or(x == 1, x == 2), y == x + 1))
8377  [[x == 1, y == 2], [x == 2, y == 3]]
8378  """
8379  t1 = _to_tactic(t1, ctx)
8380  t2 = _to_tactic(t2, ctx)
8381  if z3_debug():
8382  _z3_assert(t1.ctx == t2.ctx, "Context mismatch")
8383  return Tactic(Z3_tactic_par_and_then(t1.ctx.ref(), t1.tactic, t2.tactic), t1.ctx)
8384 
8385 
Z3_tactic_par_and_then
Z3_tactic Z3_API Z3_tactic_par_and_then(Z3_context c, Z3_tactic t1, Z3_tactic t2)
Return a tactic that applies t1 to a given goal and then t2 to every subgoal produced by t1....

Referenced by ParAndThen().

◆ PartialOrder()

def z3py.PartialOrder (   a,
  index 
)

Definition at line 11306 of file z3py.py.

11306 def PartialOrder(a, index):
11307  return FuncDeclRef(Z3_mk_partial_order(a.ctx_ref(), a.ast, index), a.ctx)
11308 
11309 
Z3_mk_partial_order
Z3_func_decl Z3_API Z3_mk_partial_order(Z3_context c, Z3_sort a, unsigned id)
create a partial ordering relation over signature a and index id.
z3py.PartialOrder
def PartialOrder(a, index)
Definition: z3py.py:11306

◆ PbEq()

def z3py.PbEq (   args,
  k,
  ctx = None 
) 
Create a Pseudo-Boolean inequality k constraint.

>>> a, b, c = Bools('a b c')
>>> f = PbEq(((a,1),(b,3),(c,2)), 3)

Definition at line 9022 of file z3py.py.

9022 def PbEq(args, k, ctx=None):
9023  """Create a Pseudo-Boolean inequality k constraint.
9024 
9025  >>> a, b, c = Bools('a b c')
9026  >>> f = PbEq(((a,1),(b,3),(c,2)), 3)
9027  """
9028  _z3_check_cint_overflow(k, "k")
9029  ctx, sz, _args, _coeffs, args = _pb_args_coeffs(args)
9030  return BoolRef(Z3_mk_pbeq(ctx.ref(), sz, _args, _coeffs, k), ctx)
9031 
9032 
Z3_mk_pbeq
Z3_ast Z3_API Z3_mk_pbeq(Z3_context c, unsigned num_args, Z3_ast const args[], int const coeffs[], int k)
Pseudo-Boolean relations.
z3py.PbEq
def PbEq(args, k, ctx=None)
Definition: z3py.py:9022

◆ PbGe()

def z3py.PbGe (   args,
  k 
) 
Create a Pseudo-Boolean inequality k constraint.

>>> a, b, c = Bools('a b c')
>>> f = PbGe(((a,1),(b,3),(c,2)), 3)

Definition at line 9011 of file z3py.py.

9011 def PbGe(args, k):
9012  """Create a Pseudo-Boolean inequality k constraint.
9013 
9014  >>> a, b, c = Bools('a b c')
9015  >>> f = PbGe(((a,1),(b,3),(c,2)), 3)
9016  """
9017  _z3_check_cint_overflow(k, "k")
9018  ctx, sz, _args, _coeffs, args = _pb_args_coeffs(args)
9019  return BoolRef(Z3_mk_pbge(ctx.ref(), sz, _args, _coeffs, k), ctx)
9020 
9021 
Z3_mk_pbge
Z3_ast Z3_API Z3_mk_pbge(Z3_context c, unsigned num_args, Z3_ast const args[], int const coeffs[], int k)
Pseudo-Boolean relations.
z3py.PbGe
def PbGe(args, k)
Definition: z3py.py:9011

◆ PbLe()

def z3py.PbLe (   args,
  k 
) 
Create a Pseudo-Boolean inequality k constraint.

>>> a, b, c = Bools('a b c')
>>> f = PbLe(((a,1),(b,3),(c,2)), 3)

Definition at line 9000 of file z3py.py.

9000 def PbLe(args, k):
9001  """Create a Pseudo-Boolean inequality k constraint.
9002 
9003  >>> a, b, c = Bools('a b c')
9004  >>> f = PbLe(((a,1),(b,3),(c,2)), 3)
9005  """
9006  _z3_check_cint_overflow(k, "k")
9007  ctx, sz, _args, _coeffs, args = _pb_args_coeffs(args)
9008  return BoolRef(Z3_mk_pble(ctx.ref(), sz, _args, _coeffs, k), ctx)
9009 
9010 
Z3_mk_pble
Z3_ast Z3_API Z3_mk_pble(Z3_context c, unsigned num_args, Z3_ast const args[], int const coeffs[], int k)
Pseudo-Boolean relations.
z3py.PbLe
def PbLe(args, k)
Definition: z3py.py:9000

◆ PiecewiseLinearOrder()

def z3py.PiecewiseLinearOrder (   a,
  index 
)

Definition at line 11318 of file z3py.py.

11318 def PiecewiseLinearOrder(a, index):
11319  return FuncDeclRef(Z3_mk_piecewise_linear_order(a.ctx_ref(), a.ast, index), a.ctx)
11320 
11321 
Z3_mk_piecewise_linear_order
Z3_func_decl Z3_API Z3_mk_piecewise_linear_order(Z3_context c, Z3_sort a, unsigned id)
create a piecewise linear ordering relation over signature a and index id.
z3py.PiecewiseLinearOrder
def PiecewiseLinearOrder(a, index)
Definition: z3py.py:11318

◆ Plus()

def z3py.Plus (   re) 
Create the regular expression accepting one or more repetitions of argument.
>>> re = Plus(Re("a"))
>>> print(simplify(InRe("aa", re)))
True
>>> print(simplify(InRe("ab", re)))
False
>>> print(simplify(InRe("", re)))
False

Definition at line 11224 of file z3py.py.

11224 def Plus(re):
11225  """Create the regular expression accepting one or more repetitions of argument.
11226  >>> re = Plus(Re("a"))
11227  >>> print(simplify(InRe("aa", re)))
11228  True
11229  >>> print(simplify(InRe("ab", re)))
11230  False
11231  >>> print(simplify(InRe("", re)))
11232  False
11233  """
11234  return ReRef(Z3_mk_re_plus(re.ctx_ref(), re.as_ast()), re.ctx)
11235 
11236 
Z3_mk_re_plus
Z3_ast Z3_API Z3_mk_re_plus(Z3_context c, Z3_ast re)
Create the regular language re+.
z3py.Plus
def Plus(re)
Definition: z3py.py:11224

◆ PrefixOf()

def z3py.PrefixOf (   a,
  b 
) 
Check if 'a' is a prefix of 'b'
>>> s1 = PrefixOf("ab", "abc")
>>> simplify(s1)
True
>>> s2 = PrefixOf("bc", "abc")
>>> simplify(s2)
False

Definition at line 10995 of file z3py.py.

10995 def PrefixOf(a, b):
10996  """Check if 'a' is a prefix of 'b'
10997  >>> s1 = PrefixOf("ab", "abc")
10998  >>> simplify(s1)
10999  True
11000  >>> s2 = PrefixOf("bc", "abc")
11001  >>> simplify(s2)
11002  False
11003  """
11004  ctx = _get_ctx2(a, b)
11005  a = _coerce_seq(a, ctx)
11006  b = _coerce_seq(b, ctx)
11007  return BoolRef(Z3_mk_seq_prefix(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
11008 
11009 
Z3_mk_seq_prefix
Z3_ast Z3_API Z3_mk_seq_prefix(Z3_context c, Z3_ast prefix, Z3_ast s)
Check if prefix is a prefix of s.
z3py.PrefixOf
def PrefixOf(a, b)
Definition: z3py.py:10995

◆ probe_description()

def z3py.probe_description (   name,
  ctx = None 
) 
Return a short description for the probe named `name`.

>>> d = probe_description('memory')

Definition at line 8666 of file z3py.py.

8666 def probe_description(name, ctx=None):
8667  """Return a short description for the probe named `name`.
8668 
8669  >>> d = probe_description('memory')
8670  """
8671  ctx = _get_ctx(ctx)
8672  return Z3_probe_get_descr(ctx.ref(), name)
8673 
8674 
Z3_probe_get_descr
Z3_string Z3_API Z3_probe_get_descr(Z3_context c, Z3_string name)
Return a string containing a description of the probe with the given name.

Referenced by describe_probes().

◆ probes()

def z3py.probes (   ctx = None) 
Return a list of all available probes in Z3.

>>> l = probes()
>>> l.count('memory') == 1
True

Definition at line 8655 of file z3py.py.

8655 def probes(ctx=None):
8656  """Return a list of all available probes in Z3.
8657 
8658  >>> l = probes()
8659  >>> l.count('memory') == 1
8660  True
8661  """
8662  ctx = _get_ctx(ctx)
8663  return [Z3_get_probe_name(ctx.ref(), i) for i in range(Z3_get_num_probes(ctx.ref()))]
8664 
8665 
Z3_get_num_probes
unsigned Z3_API Z3_get_num_probes(Z3_context c)
Return the number of builtin probes available in Z3.
Z3_get_probe_name
Z3_string Z3_API Z3_get_probe_name(Z3_context c, unsigned i)
Return the name of the i probe.

Referenced by describe_probes().

◆ Product()

def z3py.Product ( args) 
Create the product of the Z3 expressions.

>>> a, b, c = Ints('a b c')
>>> Product(a, b, c)
a*b*c
>>> Product([a, b, c])
a*b*c
>>> A = IntVector('a', 5)
>>> Product(A)
a__0*a__1*a__2*a__3*a__4

Definition at line 8907 of file z3py.py.

8907 def Product(*args):
8908  """Create the product of the Z3 expressions.
8909 
8910  >>> a, b, c = Ints('a b c')
8911  >>> Product(a, b, c)
8912  a*b*c
8913  >>> Product([a, b, c])
8914  a*b*c
8915  >>> A = IntVector('a', 5)
8916  >>> Product(A)
8917  a__0*a__1*a__2*a__3*a__4
8918  """
8919  args = _get_args(args)
8920  if len(args) == 0:
8921  return 1
8922  ctx = _ctx_from_ast_arg_list(args)
8923  if ctx is None:
8924  return _reduce(lambda a, b: a * b, args, 1)
8925  args = _coerce_expr_list(args, ctx)
8926  if is_bv(args[0]):
8927  return _reduce(lambda a, b: a * b, args, 1)
8928  else:
8929  _args, sz = _to_ast_array(args)
8930  return ArithRef(Z3_mk_mul(ctx.ref(), sz, _args), ctx)
8931 
Z3_mk_mul
Z3_ast Z3_API Z3_mk_mul(Z3_context c, unsigned num_args, Z3_ast const args[])
Create an AST node representing args[0] * ... * args[num_args-1].
z3py.Product
def Product(*args)
Definition: z3py.py:8907

◆ PropagateFunction()

def z3py.PropagateFunction (   name,
sig 
) 
Create a function that gets tracked by user propagator.
   Every term headed by this function symbol is tracked.
   If a term is fixed and the fixed callback is registered a
   callback is invoked that the term headed by this function is fixed.

Definition at line 11501 of file z3py.py.

11501 def PropagateFunction(name, *sig):
11502  """Create a function that gets tracked by user propagator.
11503  Every term headed by this function symbol is tracked.
11504  If a term is fixed and the fixed callback is registered a
11505  callback is invoked that the term headed by this function is fixed.
11506  """
11507  sig = _get_args(sig)
11508  if z3_debug():
11509  _z3_assert(len(sig) > 0, "At least two arguments expected")
11510  arity = len(sig) - 1
11511  rng = sig[arity]
11512  if z3_debug():
11513  _z3_assert(is_sort(rng), "Z3 sort expected")
11514  dom = (Sort * arity)()
11515  for i in range(arity):
11516  if z3_debug():
11517  _z3_assert(is_sort(sig[i]), "Z3 sort expected")
11518  dom[i] = sig[i].ast
11519  ctx = rng.ctx
11520  return FuncDeclRef(Z3_solver_propagate_declare(ctx.ref(), to_symbol(name, ctx), arity, dom, rng.ast), ctx)
11521 
11522 
11523 
Z3_solver_propagate_declare
Z3_func_decl Z3_API Z3_solver_propagate_declare(Z3_context c, Z3_symbol name, unsigned n, Z3_sort *domain, Z3_sort range)
z3py.PropagateFunction
def PropagateFunction(name, *sig)
Definition: z3py.py:11501

◆ prove()

def z3py.prove (   claim,
  show = False,
**  keywords 
) 
Try to prove the given claim.

This is a simple function for creating demonstrations.  It tries to prove
`claim` by showing the negation is unsatisfiable.

>>> p, q = Bools('p q')
>>> prove(Not(And(p, q)) == Or(Not(p), Not(q)))
proved

Definition at line 9094 of file z3py.py.

9094 def prove(claim, show=False, **keywords):
9095  """Try to prove the given claim.
9096 
9097  This is a simple function for creating demonstrations. It tries to prove
9098  `claim` by showing the negation is unsatisfiable.
9099 
9100  >>> p, q = Bools('p q')
9101  >>> prove(Not(And(p, q)) == Or(Not(p), Not(q)))
9102  proved
9103  """
9104  if z3_debug():
9105  _z3_assert(is_bool(claim), "Z3 Boolean expression expected")
9106  s = Solver()
9107  s.set(**keywords)
9108  s.add(Not(claim))
9109  if show:
9110  print(s)
9111  r = s.check()
9112  if r == unsat:
9113  print("proved")
9114  elif r == unknown:
9115  print("failed to prove")
9116  print(s.model())
9117  else:
9118  print("counterexample")
9119  print(s.model())
9120 
9121 
z3py.prove
def prove(claim, show=False, **keywords)
Definition: z3py.py:9094

◆ Q()

def z3py.Q (   a,
  b,
  ctx = None 
) 
Return a Z3 rational a/b.

If `ctx=None`, then the global context is used.

>>> Q(3,5)
3/5
>>> Q(3,5).sort()
Real

Definition at line 3235 of file z3py.py.

3235 def Q(a, b, ctx=None):
3236  """Return a Z3 rational a/b.
3237 
3238  If `ctx=None`, then the global context is used.
3239 
3240  >>> Q(3,5)
3241  3/5
3242  >>> Q(3,5).sort()
3243  Real
3244  """
3245  return simplify(RatVal(a, b, ctx=ctx))
3246 
3247 
z3py.simplify
def simplify(a, *arguments, **keywords)
Utils.
Definition: z3py.py:8771
z3py.Q
def Q(a, b, ctx=None)
Definition: z3py.py:3235
z3py.RatVal
def RatVal(a, b, ctx=None)
Definition: z3py.py:3219

◆ Range()

def z3py.Range (   lo,
  hi,
  ctx = None 
) 
Create the range regular expression over two sequences of length 1
>>> range = Range("a","z")
>>> print(simplify(InRe("b", range)))
True
>>> print(simplify(InRe("bb", range)))
False

Definition at line 11281 of file z3py.py.

11281 def Range(lo, hi, ctx=None):
11282  """Create the range regular expression over two sequences of length 1
11283  >>> range = Range("a","z")
11284  >>> print(simplify(InRe("b", range)))
11285  True
11286  >>> print(simplify(InRe("bb", range)))
11287  False
11288  """
11289  lo = _coerce_seq(lo, ctx)
11290  hi = _coerce_seq(hi, ctx)
11291  return ReRef(Z3_mk_re_range(lo.ctx_ref(), lo.ast, hi.ast), lo.ctx)
11292 
Z3_mk_re_range
Z3_ast Z3_API Z3_mk_re_range(Z3_context c, Z3_ast lo, Z3_ast hi)
Create the range regular expression over two sequences of length 1.
z3py.Range
def Range(lo, hi, ctx=None)
Definition: z3py.py:11281

◆ RatVal()

def z3py.RatVal (   a,
  b,
  ctx = None 
) 
Return a Z3 rational a/b.

If `ctx=None`, then the global context is used.

>>> RatVal(3,5)
3/5
>>> RatVal(3,5).sort()
Real

Definition at line 3219 of file z3py.py.

3219 def RatVal(a, b, ctx=None):
3220  """Return a Z3 rational a/b.
3221 
3222  If `ctx=None`, then the global context is used.
3223 
3224  >>> RatVal(3,5)
3225  3/5
3226  >>> RatVal(3,5).sort()
3227  Real
3228  """
3229  if z3_debug():
3230  _z3_assert(_is_int(a) or isinstance(a, str), "First argument cannot be converted into an integer")
3231  _z3_assert(_is_int(b) or isinstance(b, str), "Second argument cannot be converted into an integer")
3232  return simplify(RealVal(a, ctx) / RealVal(b, ctx))
3233 
3234 

Referenced by Q().

◆ Re()

def z3py.Re (   s,
  ctx = None 
) 
The regular expression that accepts sequence 's'
>>> s1 = Re("ab")
>>> s2 = Re(StringVal("ab"))
>>> s3 = Re(Unit(BoolVal(True)))

Definition at line 11133 of file z3py.py.

11133 def Re(s, ctx=None):
11134  """The regular expression that accepts sequence 's'
11135  >>> s1 = Re("ab")
11136  >>> s2 = Re(StringVal("ab"))
11137  >>> s3 = Re(Unit(BoolVal(True)))
11138  """
11139  s = _coerce_seq(s, ctx)
11140  return ReRef(Z3_mk_seq_to_re(s.ctx_ref(), s.as_ast()), s.ctx)
11141 
11142 
11143 # Regular expressions
11144 
Z3_mk_seq_to_re
Z3_ast Z3_API Z3_mk_seq_to_re(Z3_context c, Z3_ast seq)
Create a regular expression that accepts the sequence seq.
z3py.Re
def Re(s, ctx=None)
Definition: z3py.py:11133

◆ Real()

def z3py.Real (   name,
  ctx = None 
) 
Return a real constant named `name`. If `ctx=None`, then the global context is used.

>>> x = Real('x')
>>> is_real(x)
True
>>> is_real(x + 1)
True

Definition at line 3301 of file z3py.py.

3301 def Real(name, ctx=None):
3302  """Return a real constant named `name`. If `ctx=None`, then the global context is used.
3303 
3304  >>> x = Real('x')
3305  >>> is_real(x)
3306  True
3307  >>> is_real(x + 1)
3308  True
3309  """
3310  ctx = _get_ctx(ctx)
3311  return ArithRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), RealSort(ctx).ast), ctx)
3312 
3313 
z3py.Real
def Real(name, ctx=None)
Definition: z3py.py:3301

Referenced by Reals(), and RealVector().

◆ Reals()

def z3py.Reals (   names,
  ctx = None 
) 
Return a tuple of real constants.

>>> x, y, z = Reals('x y z')
>>> Sum(x, y, z)
x + y + z
>>> Sum(x, y, z).sort()
Real

Definition at line 3314 of file z3py.py.

3314 def Reals(names, ctx=None):
3315  """Return a tuple of real constants.
3316 
3317  >>> x, y, z = Reals('x y z')
3318  >>> Sum(x, y, z)
3319  x + y + z
3320  >>> Sum(x, y, z).sort()
3321  Real
3322  """
3323  ctx = _get_ctx(ctx)
3324  if isinstance(names, str):
3325  names = names.split(" ")
3326  return [Real(name, ctx) for name in names]
3327 
3328 
z3py.Reals
def Reals(names, ctx=None)
Definition: z3py.py:3314

◆ RealSort()

def z3py.RealSort (   ctx = None) 
Return the real sort in the given context. If `ctx=None`, then the global context is used.

>>> RealSort()
Real
>>> x = Const('x', RealSort())
>>> is_real(x)
True
>>> is_int(x)
False
>>> x.sort() == RealSort()
True

Definition at line 3155 of file z3py.py.

3155 def RealSort(ctx=None):
3156  """Return the real sort in the given context. If `ctx=None`, then the global context is used.
3157 
3158  >>> RealSort()
3159  Real
3160  >>> x = Const('x', RealSort())
3161  >>> is_real(x)
3162  True
3163  >>> is_int(x)
3164  False
3165  >>> x.sort() == RealSort()
3166  True
3167  """
3168  ctx = _get_ctx(ctx)
3169  return ArithSortRef(Z3_mk_real_sort(ctx.ref()), ctx)
3170 
3171 
Z3_mk_real_sort
Z3_sort Z3_API Z3_mk_real_sort(Z3_context c)
Create the real type.

Referenced by FreshReal(), Context.getRealSort(), Context.mkRealSort(), Real(), RealVal(), and RealVar().

◆ RealVal()

def z3py.RealVal (   val,
  ctx = None 
) 
Return a Z3 real value.

`val` may be a Python int, long, float or string representing a number in decimal or rational notation.
If `ctx=None`, then the global context is used.

>>> RealVal(1)
1
>>> RealVal(1).sort()
Real
>>> RealVal("3/5")
3/5
>>> RealVal("1.5")
3/2

Definition at line 3200 of file z3py.py.

3200 def RealVal(val, ctx=None):
3201  """Return a Z3 real value.
3202 
3203  `val` may be a Python int, long, float or string representing a number in decimal or rational notation.
3204  If `ctx=None`, then the global context is used.
3205 
3206  >>> RealVal(1)
3207  1
3208  >>> RealVal(1).sort()
3209  Real
3210  >>> RealVal("3/5")
3211  3/5
3212  >>> RealVal("1.5")
3213  3/2
3214  """
3215  ctx = _get_ctx(ctx)
3216  return RatNumRef(Z3_mk_numeral(ctx.ref(), str(val), RealSort(ctx).ast), ctx)
3217 
3218 

Referenced by Cbrt(), deserialize(), AlgebraicNumRef.index(), RatVal(), and Sqrt().

◆ RealVar()

def z3py.RealVar (   idx,
  ctx = None 
) 
Create a real free variable. Free variables are used to create quantified formulas.
They are also used to create polynomials.

>>> RealVar(0)
Var(0)

Definition at line 1485 of file z3py.py.

1485 def RealVar(idx, ctx=None):
1486  """
1487  Create a real free variable. Free variables are used to create quantified formulas.
1488  They are also used to create polynomials.
1489 
1490  >>> RealVar(0)
1491  Var(0)
1492  """
1493  return Var(idx, RealSort(ctx))
1494 
1495 
z3py.Var
def Var(idx, s)
Definition: z3py.py:1470
z3py.RealVar
def RealVar(idx, ctx=None)
Definition: z3py.py:1485

Referenced by RealVarVector().

◆ RealVarVector()

def z3py.RealVarVector (   n,
  ctx = None 
) 
Create a list of Real free variables.
The variables have ids: 0, 1, ..., n-1

>>> x0, x1, x2, x3 = RealVarVector(4)
>>> x2
Var(2)

Definition at line 1496 of file z3py.py.

1496 def RealVarVector(n, ctx=None):
1497  """
1498  Create a list of Real free variables.
1499  The variables have ids: 0, 1, ..., n-1
1500 
1501  >>> x0, x1, x2, x3 = RealVarVector(4)
1502  >>> x2
1503  Var(2)
1504  """
1505  return [RealVar(i, ctx) for i in range(n)]
1506 
z3py.RealVarVector
def RealVarVector(n, ctx=None)
Definition: z3py.py:1496

◆ RealVector()

def z3py.RealVector (   prefix,
  sz,
  ctx = None 
) 
Return a list of real constants of size `sz`.

>>> X = RealVector('x', 3)
>>> X
[x__0, x__1, x__2]
>>> Sum(X)
x__0 + x__1 + x__2
>>> Sum(X).sort()
Real

Definition at line 3329 of file z3py.py.

3329 def RealVector(prefix, sz, ctx=None):
3330  """Return a list of real constants of size `sz`.
3331 
3332  >>> X = RealVector('x', 3)
3333  >>> X
3334  [x__0, x__1, x__2]
3335  >>> Sum(X)
3336  x__0 + x__1 + x__2
3337  >>> Sum(X).sort()
3338  Real
3339  """
3340  ctx = _get_ctx(ctx)
3341  return [Real("%s__%s" % (prefix, i), ctx) for i in range(sz)]
3342 
3343 
z3py.RealVector
def RealVector(prefix, sz, ctx=None)
Definition: z3py.py:3329

◆ RecAddDefinition()

def z3py.RecAddDefinition (   f,
  args,
  body 
) 
Set the body of a recursive function.
   Recursive definitions can be simplified if they are applied to ground
   arguments.
>>> ctx = Context()
>>> fac = RecFunction('fac', IntSort(ctx), IntSort(ctx))
>>> n = Int('n', ctx)
>>> RecAddDefinition(fac, n, If(n == 0, 1, n*fac(n-1)))
>>> simplify(fac(5))
120
>>> s = Solver(ctx=ctx)
>>> s.add(fac(n) < 3)
>>> s.check()
sat
>>> s.model().eval(fac(5))
120

Definition at line 927 of file z3py.py.

927 def RecAddDefinition(f, args, body):
928  """Set the body of a recursive function.
929  Recursive definitions can be simplified if they are applied to ground
930  arguments.
931  >>> ctx = Context()
932  >>> fac = RecFunction('fac', IntSort(ctx), IntSort(ctx))
933  >>> n = Int('n', ctx)
934  >>> RecAddDefinition(fac, n, If(n == 0, 1, n*fac(n-1)))
935  >>> simplify(fac(5))
936  120
937  >>> s = Solver(ctx=ctx)
938  >>> s.add(fac(n) < 3)
939  >>> s.check()
940  sat
941  >>> s.model().eval(fac(5))
942  120
943  """
944  if is_app(args):
945  args = [args]
946  ctx = body.ctx
947  args = _get_args(args)
948  n = len(args)
949  _args = (Ast * n)()
950  for i in range(n):
951  _args[i] = args[i].ast
952  Z3_add_rec_def(ctx.ref(), f.ast, n, _args, body.ast)
953 
Z3_add_rec_def
void Z3_API Z3_add_rec_def(Z3_context c, Z3_func_decl f, unsigned n, Z3_ast args[], Z3_ast body)
Define the body of a recursive function.
z3py.RecAddDefinition
def RecAddDefinition(f, args, body)
Definition: z3py.py:927

◆ RecFunction()

def z3py.RecFunction (   name,
sig 
) 
Create a new Z3 recursive with the given sorts.

Definition at line 909 of file z3py.py.

909 def RecFunction(name, *sig):
910  """Create a new Z3 recursive with the given sorts."""
911  sig = _get_args(sig)
912  if z3_debug():
913  _z3_assert(len(sig) > 0, "At least two arguments expected")
914  arity = len(sig) - 1
915  rng = sig[arity]
916  if z3_debug():
917  _z3_assert(is_sort(rng), "Z3 sort expected")
918  dom = (Sort * arity)()
919  for i in range(arity):
920  if z3_debug():
921  _z3_assert(is_sort(sig[i]), "Z3 sort expected")
922  dom[i] = sig[i].ast
923  ctx = rng.ctx
924  return FuncDeclRef(Z3_mk_rec_func_decl(ctx.ref(), to_symbol(name, ctx), arity, dom, rng.ast), ctx)
925 
926 
Z3_mk_rec_func_decl
Z3_func_decl Z3_API Z3_mk_rec_func_decl(Z3_context c, Z3_symbol s, unsigned domain_size, Z3_sort const domain[], Z3_sort range)
Declare a recursive function.
z3py.RecFunction
def RecFunction(name, *sig)
Definition: z3py.py:909

◆ Repeat()

def z3py.Repeat (   t,
  max = 4294967295,
  ctx = None 
) 
Return a tactic that keeps applying `t` until the goal is not modified anymore
or the maximum number of iterations `max` is reached.

>>> x, y = Ints('x y')
>>> c = And(Or(x == 0, x == 1), Or(y == 0, y == 1), x > y)
>>> t = Repeat(OrElse(Tactic('split-clause'), Tactic('skip')))
>>> r = t(c)
>>> for subgoal in r: print(subgoal)
[x == 0, y == 0, x > y]
[x == 0, y == 1, x > y]
[x == 1, y == 0, x > y]
[x == 1, y == 1, x > y]
>>> t = Then(t, Tactic('propagate-values'))
>>> t(c)
[[x == 1, y == 0]]

Definition at line 8419 of file z3py.py.

8419 def Repeat(t, max=4294967295, ctx=None):
8420  """Return a tactic that keeps applying `t` until the goal is not modified anymore
8421  or the maximum number of iterations `max` is reached.
8422 
8423  >>> x, y = Ints('x y')
8424  >>> c = And(Or(x == 0, x == 1), Or(y == 0, y == 1), x > y)
8425  >>> t = Repeat(OrElse(Tactic('split-clause'), Tactic('skip')))
8426  >>> r = t(c)
8427  >>> for subgoal in r: print(subgoal)
8428  [x == 0, y == 0, x > y]
8429  [x == 0, y == 1, x > y]
8430  [x == 1, y == 0, x > y]
8431  [x == 1, y == 1, x > y]
8432  >>> t = Then(t, Tactic('propagate-values'))
8433  >>> t(c)
8434  [[x == 1, y == 0]]
8435  """
8436  t = _to_tactic(t, ctx)
8437  return Tactic(Z3_tactic_repeat(t.ctx.ref(), t.tactic, max), t.ctx)
8438 
8439 
Z3_tactic_repeat
Z3_tactic Z3_API Z3_tactic_repeat(Z3_context c, Z3_tactic t, unsigned max)
Return a tactic that keeps applying t until the goal is not modified anymore or the maximum number of...
z3py.Repeat
def Repeat(t, max=4294967295, ctx=None)
Definition: z3py.py:8419

◆ RepeatBitVec()

def z3py.RepeatBitVec (   n,
  a 
) 
Return an expression representing `n` copies of `a`.

>>> x = BitVec('x', 8)
>>> n = RepeatBitVec(4, x)
>>> n
RepeatBitVec(4, x)
>>> n.size()
32
>>> v0 = BitVecVal(10, 4)
>>> print("%.x" % v0.as_long())
a
>>> v = simplify(RepeatBitVec(4, v0))
>>> v.size()
16
>>> print("%.x" % v.as_long())
aaaa

Definition at line 4421 of file z3py.py.

4421 def RepeatBitVec(n, a):
4422  """Return an expression representing `n` copies of `a`.
4423 
4424  >>> x = BitVec('x', 8)
4425  >>> n = RepeatBitVec(4, x)
4426  >>> n
4427  RepeatBitVec(4, x)
4428  >>> n.size()
4429  32
4430  >>> v0 = BitVecVal(10, 4)
4431  >>> print("%.x" % v0.as_long())
4432  a
4433  >>> v = simplify(RepeatBitVec(4, v0))
4434  >>> v.size()
4435  16
4436  >>> print("%.x" % v.as_long())
4437  aaaa
4438  """
4439  if z3_debug():
4440  _z3_assert(_is_int(n), "First argument must be an integer")
4441  _z3_assert(is_bv(a), "Second argument must be a Z3 bit-vector expression")
4442  return BitVecRef(Z3_mk_repeat(a.ctx_ref(), n, a.as_ast()), a.ctx)
4443 
4444 
Z3_mk_repeat
Z3_ast Z3_API Z3_mk_repeat(Z3_context c, unsigned i, Z3_ast t1)
Repeat the given bit-vector up length i.
z3py.RepeatBitVec
def RepeatBitVec(n, a)
Definition: z3py.py:4421

◆ Replace()

def z3py.Replace (   s,
  src,
  dst 
) 
Replace the first occurrence of 'src' by 'dst' in 's'
>>> r = Replace("aaa", "a", "b")
>>> simplify(r)
"baa"

Definition at line 11044 of file z3py.py.

11044 def Replace(s, src, dst):
11045  """Replace the first occurrence of 'src' by 'dst' in 's'
11046  >>> r = Replace("aaa", "a", "b")
11047  >>> simplify(r)
11048  "baa"
11049  """
11050  ctx = _get_ctx2(dst, s)
11051  if ctx is None and is_expr(src):
11052  ctx = src.ctx
11053  src = _coerce_seq(src, ctx)
11054  dst = _coerce_seq(dst, ctx)
11055  s = _coerce_seq(s, ctx)
11056  return SeqRef(Z3_mk_seq_replace(src.ctx_ref(), s.as_ast(), src.as_ast(), dst.as_ast()), s.ctx)
11057 
11058 
Z3_mk_seq_replace
Z3_ast Z3_API Z3_mk_seq_replace(Z3_context c, Z3_ast s, Z3_ast src, Z3_ast dst)
Replace the first occurrence of src with dst in s.
z3py.Replace
def Replace(s, src, dst)
Definition: z3py.py:11044

◆ reset_params()

def z3py.reset_params ( ) 
Reset all global (or module) parameters.

Definition at line 295 of file z3py.py.

295 def reset_params():
296  """Reset all global (or module) parameters.
297  """
298  Z3_global_param_reset_all()
299 
300 
Z3_global_param_reset_all
void Z3_API Z3_global_param_reset_all(void)
Restore the value of all global (and module) parameters. This command will not affect already created...
z3py.reset_params
def reset_params()
Definition: z3py.py:295

◆ ReSort()

def z3py.ReSort (   s)

Definition at line 11152 of file z3py.py.

11152 def ReSort(s):
11153  if is_ast(s):
11154  return ReSortRef(Z3_mk_re_sort(s.ctx.ref(), s.ast), s.ctx)
11155  if s is None or isinstance(s, Context):
11156  ctx = _get_ctx(s)
11157  return ReSortRef(Z3_mk_re_sort(ctx.ref(), Z3_mk_string_sort(ctx.ref())), s.ctx)
11158  raise Z3Exception("Regular expression sort constructor expects either a string or a context or no argument")
11159 
11160 
Z3_mk_re_sort
Z3_sort Z3_API Z3_mk_re_sort(Z3_context c, Z3_sort seq)
Create a regular expression sort out of a sequence sort.
Z3_mk_string_sort
Z3_sort Z3_API Z3_mk_string_sort(Z3_context c)
Create a sort for unicode strings.
z3py.ReSort
def ReSort(s)
Definition: z3py.py:11152

Referenced by Context.MkReSort().

◆ RNA()

def z3py.RNA (   ctx = None)

Definition at line 9681 of file z3py.py.

9681 def RNA(ctx=None):
9682  ctx = _get_ctx(ctx)
9683  return FPRMRef(Z3_mk_fpa_round_nearest_ties_to_away(ctx.ref()), ctx)
9684 
9685 
Z3_mk_fpa_round_nearest_ties_to_away
Z3_ast Z3_API Z3_mk_fpa_round_nearest_ties_to_away(Z3_context c)
Create a numeral of RoundingMode sort which represents the NearestTiesToAway rounding mode.

Referenced by get_default_rounding_mode().

◆ RNE()

def z3py.RNE (   ctx = None)

Definition at line 9671 of file z3py.py.

9671 def RNE(ctx=None):
9672  ctx = _get_ctx(ctx)
9673  return FPRMRef(Z3_mk_fpa_round_nearest_ties_to_even(ctx.ref()), ctx)
9674 
9675 
Z3_mk_fpa_round_nearest_ties_to_even
Z3_ast Z3_API Z3_mk_fpa_round_nearest_ties_to_even(Z3_context c)
Create a numeral of RoundingMode sort which represents the NearestTiesToEven rounding mode.

Referenced by get_default_rounding_mode().

◆ RotateLeft()

def z3py.RotateLeft (   a,
  b 
) 
Return an expression representing `a` rotated to the left `b` times.

>>> a, b = BitVecs('a b', 16)
>>> RotateLeft(a, b)
RotateLeft(a, b)
>>> simplify(RotateLeft(a, 0))
a
>>> simplify(RotateLeft(a, 16))
a

Definition at line 4331 of file z3py.py.

4331 def RotateLeft(a, b):
4332  """Return an expression representing `a` rotated to the left `b` times.
4333 
4334  >>> a, b = BitVecs('a b', 16)
4335  >>> RotateLeft(a, b)
4336  RotateLeft(a, b)
4337  >>> simplify(RotateLeft(a, 0))
4338  a
4339  >>> simplify(RotateLeft(a, 16))
4340  a
4341  """
4342  _check_bv_args(a, b)
4343  a, b = _coerce_exprs(a, b)
4344  return BitVecRef(Z3_mk_ext_rotate_left(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4345 
4346 
Z3_mk_ext_rotate_left
Z3_ast Z3_API Z3_mk_ext_rotate_left(Z3_context c, Z3_ast t1, Z3_ast t2)
Rotate bits of t1 to the left t2 times.
z3py.RotateLeft
def RotateLeft(a, b)
Definition: z3py.py:4331

◆ RotateRight()

def z3py.RotateRight (   a,
  b 
) 
Return an expression representing `a` rotated to the right `b` times.

>>> a, b = BitVecs('a b', 16)
>>> RotateRight(a, b)
RotateRight(a, b)
>>> simplify(RotateRight(a, 0))
a
>>> simplify(RotateRight(a, 16))
a

Definition at line 4347 of file z3py.py.

4347 def RotateRight(a, b):
4348  """Return an expression representing `a` rotated to the right `b` times.
4349 
4350  >>> a, b = BitVecs('a b', 16)
4351  >>> RotateRight(a, b)
4352  RotateRight(a, b)
4353  >>> simplify(RotateRight(a, 0))
4354  a
4355  >>> simplify(RotateRight(a, 16))
4356  a
4357  """
4358  _check_bv_args(a, b)
4359  a, b = _coerce_exprs(a, b)
4360  return BitVecRef(Z3_mk_ext_rotate_right(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4361 
4362 
Z3_mk_ext_rotate_right
Z3_ast Z3_API Z3_mk_ext_rotate_right(Z3_context c, Z3_ast t1, Z3_ast t2)
Rotate bits of t1 to the right t2 times.
z3py.RotateRight
def RotateRight(a, b)
Definition: z3py.py:4347

◆ RoundNearestTiesToAway()

def z3py.RoundNearestTiesToAway (   ctx = None)

Definition at line 9676 of file z3py.py.

9676 def RoundNearestTiesToAway(ctx=None):
9677  ctx = _get_ctx(ctx)
9678  return FPRMRef(Z3_mk_fpa_round_nearest_ties_to_away(ctx.ref()), ctx)
9679 
9680 
z3py.RoundNearestTiesToAway
def RoundNearestTiesToAway(ctx=None)
Definition: z3py.py:9676

◆ RoundNearestTiesToEven()

def z3py.RoundNearestTiesToEven (   ctx = None)

Definition at line 9666 of file z3py.py.

9666 def RoundNearestTiesToEven(ctx=None):
9667  ctx = _get_ctx(ctx)
9668  return FPRMRef(Z3_mk_fpa_round_nearest_ties_to_even(ctx.ref()), ctx)
9669 
9670 
z3py.RoundNearestTiesToEven
def RoundNearestTiesToEven(ctx=None)
Definition: z3py.py:9666

◆ RoundTowardNegative()

def z3py.RoundTowardNegative (   ctx = None)

Definition at line 9696 of file z3py.py.

9696 def RoundTowardNegative(ctx=None):
9697  ctx = _get_ctx(ctx)
9698  return FPRMRef(Z3_mk_fpa_round_toward_negative(ctx.ref()), ctx)
9699 
9700 
Z3_mk_fpa_round_toward_negative
Z3_ast Z3_API Z3_mk_fpa_round_toward_negative(Z3_context c)
Create a numeral of RoundingMode sort which represents the TowardNegative rounding mode.
z3py.RoundTowardNegative
def RoundTowardNegative(ctx=None)
Definition: z3py.py:9696

◆ RoundTowardPositive()

def z3py.RoundTowardPositive (   ctx = None)

Definition at line 9686 of file z3py.py.

9686 def RoundTowardPositive(ctx=None):
9687  ctx = _get_ctx(ctx)
9688  return FPRMRef(Z3_mk_fpa_round_toward_positive(ctx.ref()), ctx)
9689 
9690 
Z3_mk_fpa_round_toward_positive
Z3_ast Z3_API Z3_mk_fpa_round_toward_positive(Z3_context c)
Create a numeral of RoundingMode sort which represents the TowardPositive rounding mode.
z3py.RoundTowardPositive
def RoundTowardPositive(ctx=None)
Definition: z3py.py:9686

◆ RoundTowardZero()

def z3py.RoundTowardZero (   ctx = None)

Definition at line 9706 of file z3py.py.

9706 def RoundTowardZero(ctx=None):
9707  ctx = _get_ctx(ctx)
9708  return FPRMRef(Z3_mk_fpa_round_toward_zero(ctx.ref()), ctx)
9709 
9710 
Z3_mk_fpa_round_toward_zero
Z3_ast Z3_API Z3_mk_fpa_round_toward_zero(Z3_context c)
Create a numeral of RoundingMode sort which represents the TowardZero rounding mode.
z3py.RoundTowardZero
def RoundTowardZero(ctx=None)
Definition: z3py.py:9706

◆ RTN()

def z3py.RTN (   ctx = None)

Definition at line 9701 of file z3py.py.

9701 def RTN(ctx=None):
9702  ctx = _get_ctx(ctx)
9703  return FPRMRef(Z3_mk_fpa_round_toward_negative(ctx.ref()), ctx)
9704 
9705 

Referenced by get_default_rounding_mode().

◆ RTP()

def z3py.RTP (   ctx = None)

Definition at line 9691 of file z3py.py.

9691 def RTP(ctx=None):
9692  ctx = _get_ctx(ctx)
9693  return FPRMRef(Z3_mk_fpa_round_toward_positive(ctx.ref()), ctx)
9694 
9695 

Referenced by get_default_rounding_mode().

◆ RTZ()

def z3py.RTZ (   ctx = None)

Definition at line 9711 of file z3py.py.

9711 def RTZ(ctx=None):
9712  ctx = _get_ctx(ctx)
9713  return FPRMRef(Z3_mk_fpa_round_toward_zero(ctx.ref()), ctx)
9714 
9715 

Referenced by get_default_rounding_mode().

◆ Select()

def z3py.Select (   a,
args 
) 
Return a Z3 select array expression.

>>> a = Array('a', IntSort(), IntSort())
>>> i = Int('i')
>>> Select(a, i)
a[i]
>>> eq(Select(a, i), a[i])
True

Definition at line 4807 of file z3py.py.

4807 def Select(a, *args):
4808  """Return a Z3 select array expression.
4809 
4810  >>> a = Array('a', IntSort(), IntSort())
4811  >>> i = Int('i')
4812  >>> Select(a, i)
4813  a[i]
4814  >>> eq(Select(a, i), a[i])
4815  True
4816  """
4817  args = _get_args(args)
4818  if z3_debug():
4819  _z3_assert(is_array_sort(a), "First argument must be a Z3 array expression")
4820  return a[args]
4821 
4822 
z3py.Select
def Select(a, *args)
Definition: z3py.py:4807

◆ SeqSort()

def z3py.SeqSort (   s) 
Create a sequence sort over elements provided in the argument
>>> s = SeqSort(IntSort())
>>> s == Unit(IntVal(1)).sort()
True

Definition at line 10765 of file z3py.py.

10765 def SeqSort(s):
10766  """Create a sequence sort over elements provided in the argument
10767  >>> s = SeqSort(IntSort())
10768  >>> s == Unit(IntVal(1)).sort()
10769  True
10770  """
10771  return SeqSortRef(Z3_mk_seq_sort(s.ctx_ref(), s.ast), s.ctx)
10772 
10773 
Z3_mk_seq_sort
Z3_sort Z3_API Z3_mk_seq_sort(Z3_context c, Z3_sort s)
Create a sequence sort out of the sort for the elements.
z3py.SeqSort
def SeqSort(s)
Definition: z3py.py:10765

Referenced by Context.MkSeqSort().

◆ set_default_fp_sort()

def z3py.set_default_fp_sort (   ebits,
  sbits,
  ctx = None 
)

Definition at line 9327 of file z3py.py.

9327 def set_default_fp_sort(ebits, sbits, ctx=None):
9328  global _dflt_fpsort_ebits
9329  global _dflt_fpsort_sbits
9330  _dflt_fpsort_ebits = ebits
9331  _dflt_fpsort_sbits = sbits
9332 
9333 
z3py.set_default_fp_sort
def set_default_fp_sort(ebits, sbits, ctx=None)
Definition: z3py.py:9327

◆ set_default_rounding_mode()

def z3py.set_default_rounding_mode (   rm,
  ctx = None 
)

Definition at line 9314 of file z3py.py.

9314 def set_default_rounding_mode(rm, ctx=None):
9315  global _dflt_rounding_mode
9316  if is_fprm_value(rm):
9317  _dflt_rounding_mode = rm.decl().kind()
9318  else:
9319  _z3_assert(_dflt_rounding_mode in _ROUNDING_MODES, "illegal rounding mode")
9320  _dflt_rounding_mode = rm
9321 
9322 
z3py.set_default_rounding_mode
def set_default_rounding_mode(rm, ctx=None)
Definition: z3py.py:9314

◆ set_option()

def z3py.set_option ( args,
**  kws 
) 
Alias for 'set_param' for backward compatibility.

Definition at line 301 of file z3py.py.

301 def set_option(*args, **kws):
302  """Alias for 'set_param' for backward compatibility.
303  """
304  return set_param(*args, **kws)
305 
306 
z3py.set_option
def set_option(*args, **kws)
Definition: z3py.py:301
z3py.set_param
def set_param(*args, **kws)
Definition: z3py.py:271

◆ set_param()

def z3py.set_param ( args,
**  kws 
) 
Set Z3 global (or module) parameters.

>>> set_param(precision=10)

Definition at line 271 of file z3py.py.

271 def set_param(*args, **kws):
272  """Set Z3 global (or module) parameters.
273 
274  >>> set_param(precision=10)
275  """
276  if z3_debug():
277  _z3_assert(len(args) % 2 == 0, "Argument list must have an even number of elements.")
278  new_kws = {}
279  for k in kws:
280  v = kws[k]
281  if not set_pp_option(k, v):
282  new_kws[k] = v
283  for key in new_kws:
284  value = new_kws[key]
285  Z3_global_param_set(str(key).upper(), _to_param_value(value))
286  prev = None
287  for a in args:
288  if prev is None:
289  prev = a
290  else:
291  Z3_global_param_set(str(prev), _to_param_value(a))
292  prev = None
293 
294 
Z3_global_param_set
void Z3_API Z3_global_param_set(Z3_string param_id, Z3_string param_value)
Set a global (or module) parameter. This setting is shared by all Z3 contexts.

Referenced by set_option().

◆ SetAdd()

def z3py.SetAdd (   s,
  e 
) 
 Add element e to set s
>>> a = Const('a', SetSort(IntSort()))
>>> SetAdd(a, 1)
Store(a, 1, True)

Definition at line 4966 of file z3py.py.

4966 def SetAdd(s, e):
4967  """ Add element e to set s
4968  >>> a = Const('a', SetSort(IntSort()))
4969  >>> SetAdd(a, 1)
4970  Store(a, 1, True)
4971  """
4972  ctx = _ctx_from_ast_arg_list([s, e])
4973  e = _py2expr(e, ctx)
4974  return ArrayRef(Z3_mk_set_add(ctx.ref(), s.as_ast(), e.as_ast()), ctx)
4975 
4976 
Z3_mk_set_add
Z3_ast Z3_API Z3_mk_set_add(Z3_context c, Z3_ast set, Z3_ast elem)
Add an element to a set.
z3py.SetAdd
def SetAdd(s, e)
Definition: z3py.py:4966

◆ SetComplement()

def z3py.SetComplement (   s) 
 The complement of set s
>>> a = Const('a', SetSort(IntSort()))
>>> SetComplement(a)
complement(a)

Definition at line 4988 of file z3py.py.

4988 def SetComplement(s):
4989  """ The complement of set s
4990  >>> a = Const('a', SetSort(IntSort()))
4991  >>> SetComplement(a)
4992  complement(a)
4993  """
4994  ctx = s.ctx
4995  return ArrayRef(Z3_mk_set_complement(ctx.ref(), s.as_ast()), ctx)
4996 
4997 
Z3_mk_set_complement
Z3_ast Z3_API Z3_mk_set_complement(Z3_context c, Z3_ast arg)
Take the complement of a set.
z3py.SetComplement
def SetComplement(s)
Definition: z3py.py:4988

◆ SetDel()

def z3py.SetDel (   s,
  e 
) 
 Remove element e to set s
>>> a = Const('a', SetSort(IntSort()))
>>> SetDel(a, 1)
Store(a, 1, False)

Definition at line 4977 of file z3py.py.

4977 def SetDel(s, e):
4978  """ Remove element e to set s
4979  >>> a = Const('a', SetSort(IntSort()))
4980  >>> SetDel(a, 1)
4981  Store(a, 1, False)
4982  """
4983  ctx = _ctx_from_ast_arg_list([s, e])
4984  e = _py2expr(e, ctx)
4985  return ArrayRef(Z3_mk_set_del(ctx.ref(), s.as_ast(), e.as_ast()), ctx)
4986 
4987 
Z3_mk_set_del
Z3_ast Z3_API Z3_mk_set_del(Z3_context c, Z3_ast set, Z3_ast elem)
Remove an element to a set.
z3py.SetDel
def SetDel(s, e)
Definition: z3py.py:4977

◆ SetDifference()

def z3py.SetDifference (   a,
  b 
) 
 The set difference of a and b
>>> a = Const('a', SetSort(IntSort()))
>>> b = Const('b', SetSort(IntSort()))
>>> SetDifference(a, b)
setminus(a, b)

Definition at line 4998 of file z3py.py.

4998 def SetDifference(a, b):
4999  """ The set difference of a and b
5000  >>> a = Const('a', SetSort(IntSort()))
5001  >>> b = Const('b', SetSort(IntSort()))
5002  >>> SetDifference(a, b)
5003  setminus(a, b)
5004  """
5005  ctx = _ctx_from_ast_arg_list([a, b])
5006  return ArrayRef(Z3_mk_set_difference(ctx.ref(), a.as_ast(), b.as_ast()), ctx)
5007 
5008 
Z3_mk_set_difference
Z3_ast Z3_API Z3_mk_set_difference(Z3_context c, Z3_ast arg1, Z3_ast arg2)
Take the set difference between two sets.
z3py.SetDifference
def SetDifference(a, b)
Definition: z3py.py:4998

◆ SetHasSize()

def z3py.SetHasSize (   a,
  k 
)

Definition at line 4880 of file z3py.py.

4880 def SetHasSize(a, k):
4881  ctx = a.ctx
4882  k = _py2expr(k, ctx)
4883  return _to_expr_ref(Z3_mk_set_has_size(ctx.ref(), a.as_ast(), k.as_ast()), ctx)
4884 
4885 
Z3_mk_set_has_size
Z3_ast Z3_API Z3_mk_set_has_size(Z3_context c, Z3_ast set, Z3_ast k)
Create predicate that holds if Boolean array set has k elements set to true.
z3py.SetHasSize
def SetHasSize(a, k)
Definition: z3py.py:4880

◆ SetIntersect()

def z3py.SetIntersect ( args) 
 Take the union of sets
>>> a = Const('a', SetSort(IntSort()))
>>> b = Const('b', SetSort(IntSort()))
>>> SetIntersect(a, b)
intersection(a, b)

Definition at line 4953 of file z3py.py.

4953 def SetIntersect(*args):
4954  """ Take the union of sets
4955  >>> a = Const('a', SetSort(IntSort()))
4956  >>> b = Const('b', SetSort(IntSort()))
4957  >>> SetIntersect(a, b)
4958  intersection(a, b)
4959  """
4960  args = _get_args(args)
4961  ctx = _ctx_from_ast_arg_list(args)
4962  _args, sz = _to_ast_array(args)
4963  return ArrayRef(Z3_mk_set_intersect(ctx.ref(), sz, _args), ctx)
4964 
4965 
Z3_mk_set_intersect
Z3_ast Z3_API Z3_mk_set_intersect(Z3_context c, unsigned num_args, Z3_ast const args[])
Take the intersection of a list of sets.
z3py.SetIntersect
def SetIntersect(*args)
Definition: z3py.py:4953

◆ SetSort()

def z3py.SetSort (   s)

Sets. 

 Create a set sort over element sort s

Definition at line 4917 of file z3py.py.

4917 def SetSort(s):
4918  """ Create a set sort over element sort s"""
4919  return ArraySort(s, BoolSort())
4920 
4921 
z3py.SetSort
def SetSort(s)
Sets.
Definition: z3py.py:4917

Referenced by Context.MkSetSort().

◆ SetUnion()

def z3py.SetUnion ( args) 
 Take the union of sets
>>> a = Const('a', SetSort(IntSort()))
>>> b = Const('b', SetSort(IntSort()))
>>> SetUnion(a, b)
union(a, b)

Definition at line 4940 of file z3py.py.

4940 def SetUnion(*args):
4941  """ Take the union of sets
4942  >>> a = Const('a', SetSort(IntSort()))
4943  >>> b = Const('b', SetSort(IntSort()))
4944  >>> SetUnion(a, b)
4945  union(a, b)
4946  """
4947  args = _get_args(args)
4948  ctx = _ctx_from_ast_arg_list(args)
4949  _args, sz = _to_ast_array(args)
4950  return ArrayRef(Z3_mk_set_union(ctx.ref(), sz, _args), ctx)
4951 
4952 
Z3_mk_set_union
Z3_ast Z3_API Z3_mk_set_union(Z3_context c, unsigned num_args, Z3_ast const args[])
Take the union of a list of sets.
z3py.SetUnion
def SetUnion(*args)
Definition: z3py.py:4940

◆ SignExt()

def z3py.SignExt (   n,
  a 
) 
Return a bit-vector expression with `n` extra sign-bits.

>>> x = BitVec('x', 16)
>>> n = SignExt(8, x)
>>> n.size()
24
>>> n
SignExt(8, x)
>>> n.sort()
BitVec(24)
>>> v0 = BitVecVal(2, 2)
>>> v0
2
>>> v0.size()
2
>>> v  = simplify(SignExt(6, v0))
>>> v
254
>>> v.size()
8
>>> print("%.x" % v.as_long())
fe

Definition at line 4363 of file z3py.py.

4363 def SignExt(n, a):
4364  """Return a bit-vector expression with `n` extra sign-bits.
4365 
4366  >>> x = BitVec('x', 16)
4367  >>> n = SignExt(8, x)
4368  >>> n.size()
4369  24
4370  >>> n
4371  SignExt(8, x)
4372  >>> n.sort()
4373  BitVec(24)
4374  >>> v0 = BitVecVal(2, 2)
4375  >>> v0
4376  2
4377  >>> v0.size()
4378  2
4379  >>> v = simplify(SignExt(6, v0))
4380  >>> v
4381  254
4382  >>> v.size()
4383  8
4384  >>> print("%.x" % v.as_long())
4385  fe
4386  """
4387  if z3_debug():
4388  _z3_assert(_is_int(n), "First argument must be an integer")
4389  _z3_assert(is_bv(a), "Second argument must be a Z3 bit-vector expression")
4390  return BitVecRef(Z3_mk_sign_ext(a.ctx_ref(), n, a.as_ast()), a.ctx)
4391 
4392 
Z3_mk_sign_ext
Z3_ast Z3_API Z3_mk_sign_ext(Z3_context c, unsigned i, Z3_ast t1)
Sign-extend of the given bit-vector to the (signed) equivalent bit-vector of size m+i,...
z3py.SignExt
def SignExt(n, a)
Definition: z3py.py:4363

◆ SimpleSolver()

def z3py.SimpleSolver (   ctx = None,
  logFile = None 
) 
Return a simple general purpose solver with limited amount of preprocessing.

>>> s = SimpleSolver()
>>> x = Int('x')
>>> s.add(x > 0)
>>> s.check()
sat

Definition at line 7419 of file z3py.py.

7419 def SimpleSolver(ctx=None, logFile=None):
7420  """Return a simple general purpose solver with limited amount of preprocessing.
7421 
7422  >>> s = SimpleSolver()
7423  >>> x = Int('x')
7424  >>> s.add(x > 0)
7425  >>> s.check()
7426  sat
7427  """
7428  ctx = _get_ctx(ctx)
7429  return Solver(Z3_mk_simple_solver(ctx.ref()), ctx, logFile)
7430 
Z3_mk_simple_solver
Z3_solver Z3_API Z3_mk_simple_solver(Z3_context c)
Create a new incremental solver.
z3py.SimpleSolver
def SimpleSolver(ctx=None, logFile=None)
Definition: z3py.py:7419

◆ simplify()

def z3py.simplify (   a,
arguments,
**  keywords 
)

Utils. 

Simplify the expression `a` using the given options.

This function has many options. Use `help_simplify` to obtain the complete list.

>>> x = Int('x')
>>> y = Int('y')
>>> simplify(x + 1 + y + x + 1)
2 + 2*x + y
>>> simplify((x + 1)*(y + 1), som=True)
1 + x + y + x*y
>>> simplify(Distinct(x, y, 1), blast_distinct=True)
And(Not(x == y), Not(x == 1), Not(y == 1))
>>> simplify(And(x == 0, y == 1), elim_and=True)
Not(Or(Not(x == 0), Not(y == 1)))

Definition at line 8771 of file z3py.py.

8771 def simplify(a, *arguments, **keywords):
8772  """Simplify the expression `a` using the given options.
8773 
8774  This function has many options. Use `help_simplify` to obtain the complete list.
8775 
8776  >>> x = Int('x')
8777  >>> y = Int('y')
8778  >>> simplify(x + 1 + y + x + 1)
8779  2 + 2*x + y
8780  >>> simplify((x + 1)*(y + 1), som=True)
8781  1 + x + y + x*y
8782  >>> simplify(Distinct(x, y, 1), blast_distinct=True)
8783  And(Not(x == y), Not(x == 1), Not(y == 1))
8784  >>> simplify(And(x == 0, y == 1), elim_and=True)
8785  Not(Or(Not(x == 0), Not(y == 1)))
8786  """
8787  if z3_debug():
8788  _z3_assert(is_expr(a), "Z3 expression expected")
8789  if len(arguments) > 0 or len(keywords) > 0:
8790  p = args2params(arguments, keywords, a.ctx)
8791  return _to_expr_ref(Z3_simplify_ex(a.ctx_ref(), a.as_ast(), p.params), a.ctx)
8792  else:
8793  return _to_expr_ref(Z3_simplify(a.ctx_ref(), a.as_ast()), a.ctx)
8794 
8795 
Z3_simplify
Z3_ast Z3_API Z3_simplify(Z3_context c, Z3_ast a)
Interface to simplifier.
Z3_simplify_ex
Z3_ast Z3_API Z3_simplify_ex(Z3_context c, Z3_ast a, Z3_params p)
Interface to simplifier.

Referenced by Q(), RatVal(), and Expr< R extends Sort >.simplify().

◆ simplify_param_descrs()

def z3py.simplify_param_descrs ( ) 
Return the set of parameter descriptions for Z3 `simplify` procedure.

Definition at line 8801 of file z3py.py.

8801 def simplify_param_descrs():
8802  """Return the set of parameter descriptions for Z3 `simplify` procedure."""
8803  return ParamDescrsRef(Z3_simplify_get_param_descrs(main_ctx().ref()), main_ctx())
8804 
8805 
Z3_simplify_get_param_descrs
Z3_param_descrs Z3_API Z3_simplify_get_param_descrs(Z3_context c)
Return the parameter description set for the simplify procedure.
z3py.simplify_param_descrs
def simplify_param_descrs()
Definition: z3py.py:8801

◆ solve()

def z3py.solve ( args,
**  keywords 
) 
Solve the constraints `*args`.

This is a simple function for creating demonstrations. It creates a solver,
configure it using the options in `keywords`, adds the constraints
in `args`, and invokes check.

>>> a = Int('a')
>>> solve(a > 0, a < 2)
[a = 1]

Definition at line 9033 of file z3py.py.

9033 def solve(*args, **keywords):
9034  """Solve the constraints `*args`.
9035 
9036  This is a simple function for creating demonstrations. It creates a solver,
9037  configure it using the options in `keywords`, adds the constraints
9038  in `args`, and invokes check.
9039 
9040  >>> a = Int('a')
9041  >>> solve(a > 0, a < 2)
9042  [a = 1]
9043  """
9044  show = keywords.pop("show", False)
9045  s = Solver()
9046  s.set(**keywords)
9047  s.add(*args)
9048  if show:
9049  print(s)
9050  r = s.check()
9051  if r == unsat:
9052  print("no solution")
9053  elif r == unknown:
9054  print("failed to solve")
9055  try:
9056  print(s.model())
9057  except Z3Exception:
9058  return
9059  else:
9060  print(s.model())
9061 
9062 
z3py.solve
def solve(*args, **keywords)
Definition: z3py.py:9033

◆ solve_using()

def z3py.solve_using (   s,
args,
**  keywords 
) 
Solve the constraints `*args` using solver `s`.

This is a simple function for creating demonstrations. It is similar to `solve`,
but it uses the given solver `s`.
It configures solver `s` using the options in `keywords`, adds the constraints
in `args`, and invokes check.

Definition at line 9063 of file z3py.py.

9063 def solve_using(s, *args, **keywords):
9064  """Solve the constraints `*args` using solver `s`.
9065 
9066  This is a simple function for creating demonstrations. It is similar to `solve`,
9067  but it uses the given solver `s`.
9068  It configures solver `s` using the options in `keywords`, adds the constraints
9069  in `args`, and invokes check.
9070  """
9071  show = keywords.pop("show", False)
9072  if z3_debug():
9073  _z3_assert(isinstance(s, Solver), "Solver object expected")
9074  s.set(**keywords)
9075  s.add(*args)
9076  if show:
9077  print("Problem:")
9078  print(s)
9079  r = s.check()
9080  if r == unsat:
9081  print("no solution")
9082  elif r == unknown:
9083  print("failed to solve")
9084  try:
9085  print(s.model())
9086  except Z3Exception:
9087  return
9088  else:
9089  if show:
9090  print("Solution:")
9091  print(s.model())
9092 
9093 
z3py.solve_using
def solve_using(s, *args, **keywords)
Definition: z3py.py:9063

◆ SolverFor()

def z3py.SolverFor (   logic,
  ctx = None,
  logFile = None 
) 
Create a solver customized for the given logic.

The parameter `logic` is a string. It should be contains
the name of a SMT-LIB logic.
See http://www.smtlib.org/ for the name of all available logics.

>>> s = SolverFor("QF_LIA")
>>> x = Int('x')
>>> s.add(x > 0)
>>> s.add(x < 2)
>>> s.check()
sat
>>> s.model()
[x = 1]

Definition at line 7398 of file z3py.py.

7398 def SolverFor(logic, ctx=None, logFile=None):
7399  """Create a solver customized for the given logic.
7400 
7401  The parameter `logic` is a string. It should be contains
7402  the name of a SMT-LIB logic.
7403  See http://www.smtlib.org/ for the name of all available logics.
7404 
7405  >>> s = SolverFor("QF_LIA")
7406  >>> x = Int('x')
7407  >>> s.add(x > 0)
7408  >>> s.add(x < 2)
7409  >>> s.check()
7410  sat
7411  >>> s.model()
7412  [x = 1]
7413  """
7414  ctx = _get_ctx(ctx)
7415  logic = to_symbol(logic)
7416  return Solver(Z3_mk_solver_for_logic(ctx.ref(), logic), ctx, logFile)
7417 
7418 
Z3_mk_solver_for_logic
Z3_solver Z3_API Z3_mk_solver_for_logic(Z3_context c, Z3_symbol logic)
Create a new solver customized for the given logic. It behaves like Z3_mk_solver if the logic is unkn...
z3py.SolverFor
def SolverFor(logic, ctx=None, logFile=None)
Definition: z3py.py:7398

◆ Sqrt()

def z3py.Sqrt (   a,
  ctx = None 
) 
 Return a Z3 expression which represents the square root of a.

>>> x = Real('x')
>>> Sqrt(x)
x**(1/2)

Definition at line 3411 of file z3py.py.

3411 def Sqrt(a, ctx=None):
3412  """ Return a Z3 expression which represents the square root of a.
3413 
3414  >>> x = Real('x')
3415  >>> Sqrt(x)
3416  x**(1/2)
3417  """
3418  if not is_expr(a):
3419  ctx = _get_ctx(ctx)
3420  a = RealVal(a, ctx)
3421  return a ** "1/2"
3422 
3423 
z3py.Sqrt
def Sqrt(a, ctx=None)
Definition: z3py.py:3411

◆ SRem()

def z3py.SRem (   a,
  b 
) 
Create the Z3 expression signed remainder.

Use the operator % for signed modulus, and URem() for unsigned remainder.

>>> x = BitVec('x', 32)
>>> y = BitVec('y', 32)
>>> SRem(x, y)
SRem(x, y)
>>> SRem(x, y).sort()
BitVec(32)
>>> (x % y).sexpr()
'(bvsmod x y)'
>>> SRem(x, y).sexpr()
'(bvsrem x y)'

Definition at line 4278 of file z3py.py.

4278 def SRem(a, b):
4279  """Create the Z3 expression signed remainder.
4280 
4281  Use the operator % for signed modulus, and URem() for unsigned remainder.
4282 
4283  >>> x = BitVec('x', 32)
4284  >>> y = BitVec('y', 32)
4285  >>> SRem(x, y)
4286  SRem(x, y)
4287  >>> SRem(x, y).sort()
4288  BitVec(32)
4289  >>> (x % y).sexpr()
4290  '(bvsmod x y)'
4291  >>> SRem(x, y).sexpr()
4292  '(bvsrem x y)'
4293  """
4294  _check_bv_args(a, b)
4295  a, b = _coerce_exprs(a, b)
4296  return BitVecRef(Z3_mk_bvsrem(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4297 
4298 
Z3_mk_bvsrem
Z3_ast Z3_API Z3_mk_bvsrem(Z3_context c, Z3_ast t1, Z3_ast t2)
Two's complement signed remainder (sign follows dividend).
z3py.SRem
def SRem(a, b)
Definition: z3py.py:4278

◆ Star()

def z3py.Star (   re) 
Create the regular expression accepting zero or more repetitions of argument.
>>> re = Star(Re("a"))
>>> print(simplify(InRe("aa", re)))
True
>>> print(simplify(InRe("ab", re)))
False
>>> print(simplify(InRe("", re)))
True

Definition at line 11255 of file z3py.py.

11255 def Star(re):
11256  """Create the regular expression accepting zero or more repetitions of argument.
11257  >>> re = Star(Re("a"))
11258  >>> print(simplify(InRe("aa", re)))
11259  True
11260  >>> print(simplify(InRe("ab", re)))
11261  False
11262  >>> print(simplify(InRe("", re)))
11263  True
11264  """
11265  return ReRef(Z3_mk_re_star(re.ctx_ref(), re.as_ast()), re.ctx)
11266 
11267 
Z3_mk_re_star
Z3_ast Z3_API Z3_mk_re_star(Z3_context c, Z3_ast re)
Create the regular language re*.
z3py.Star
def Star(re)
Definition: z3py.py:11255

◆ Store()

def z3py.Store (   a,
args 
) 
Return a Z3 store array expression.

>>> a    = Array('a', IntSort(), IntSort())
>>> i, v = Ints('i v')
>>> s    = Store(a, i, v)
>>> s.sort()
Array(Int, Int)
>>> prove(s[i] == v)
proved
>>> j    = Int('j')
>>> prove(Implies(i != j, s[j] == a[j]))
proved

Definition at line 4790 of file z3py.py.

4790 def Store(a, *args):
4791  """Return a Z3 store array expression.
4792 
4793  >>> a = Array('a', IntSort(), IntSort())
4794  >>> i, v = Ints('i v')
4795  >>> s = Store(a, i, v)
4796  >>> s.sort()
4797  Array(Int, Int)
4798  >>> prove(s[i] == v)
4799  proved
4800  >>> j = Int('j')
4801  >>> prove(Implies(i != j, s[j] == a[j]))
4802  proved
4803  """
4804  return Update(a, args)
4805 
4806 
z3py.Update
def Update(a, *args)
Definition: z3py.py:4747
z3py.Store
def Store(a, *args)
Definition: z3py.py:4790

Referenced by ModelRef.get_interp().

◆ StrFromCode()

def z3py.StrFromCode (   c) 
Convert code to a string

Definition at line 11127 of file z3py.py.

11127 def StrFromCode(c):
11128  """Convert code to a string"""
11129  if not is_expr(c):
11130  c = _py2expr(c)
11131  return SeqRef(Z3_mk_string_from_code(c.ctx_ref(), c.as_ast()), c.ctx)
11132 
Z3_mk_string_from_code
Z3_ast Z3_API Z3_mk_string_from_code(Z3_context c, Z3_ast a)
Code to string conversion.
z3py.StrFromCode
def StrFromCode(c)
Definition: z3py.py:11127

◆ String()

def z3py.String (   name,
  ctx = None 
) 
Return a string constant named `name`. If `ctx=None`, then the global context is used.

>>> x = String('x')

Definition at line 10928 of file z3py.py.

10928 def String(name, ctx=None):
10929  """Return a string constant named `name`. If `ctx=None`, then the global context is used.
10930 
10931  >>> x = String('x')
10932  """
10933  ctx = _get_ctx(ctx)
10934  return SeqRef(Z3_mk_const(ctx.ref(), to_symbol(name, ctx), StringSort(ctx).ast), ctx)
10935 
10936 
z3py.StringSort
def StringSort(ctx=None)
Definition: z3py.py:10746
z3py.String
def String(name, ctx=None)
Definition: z3py.py:10928

Referenced by Context.Context(), Statistics.getEntries(), Statistics.getKeys(), Context.getProbeNames(), Context.getTacticNames(), Context.mkString(), Strings(), and FuncInterp< R extends Sort >.toString().

◆ Strings()

def z3py.Strings (   names,
  ctx = None 
) 
Return a tuple of String constants.

Definition at line 10937 of file z3py.py.

10937 def Strings(names, ctx=None):
10938  """Return a tuple of String constants. """
10939  ctx = _get_ctx(ctx)
10940  if isinstance(names, str):
10941  names = names.split(" ")
10942  return [String(name, ctx) for name in names]
10943 
10944 
z3py.Strings
def Strings(names, ctx=None)
Definition: z3py.py:10937

◆ StringSort()

def z3py.StringSort (   ctx = None) 
Create a string sort
>>> s = StringSort()
>>> print(s)
String

Definition at line 10746 of file z3py.py.

10746 def StringSort(ctx=None):
10747  """Create a string sort
10748  >>> s = StringSort()
10749  >>> print(s)
10750  String
10751  """
10752  ctx = _get_ctx(ctx)
10753  return SeqSortRef(Z3_mk_string_sort(ctx.ref()), ctx)
10754 

Referenced by String().

◆ StringVal()

def z3py.StringVal (   s,
  ctx = None 
) 
create a string expression

Definition at line 10921 of file z3py.py.

10921 def StringVal(s, ctx=None):
10922  """create a string expression"""
10923  s = "".join(str(ch) if 32 <= ord(ch) and ord(ch) < 127 else "\\u{%x}" % (ord(ch)) for ch in s)
10924  ctx = _get_ctx(ctx)
10925  return SeqRef(Z3_mk_string(ctx.ref(), s), ctx)
10926 
10927 
Z3_mk_string
Z3_ast Z3_API Z3_mk_string(Z3_context c, Z3_string s)
Create a string constant out of the string that is passed in The string may contain escape encoding f...

Referenced by CharIsDigit(), deserialize(), Extract(), and AlgebraicNumRef.index().

◆ StrToCode()

def z3py.StrToCode (   s) 
Convert a unit length string to integer code

Definition at line 11121 of file z3py.py.

11121 def StrToCode(s):
11122  """Convert a unit length string to integer code"""
11123  if not is_expr(s):
11124  s = _py2expr(s)
11125  return ArithRef(Z3_mk_string_to_code(s.ctx_ref(), s.as_ast()), s.ctx)
11126 
Z3_mk_string_to_code
Z3_ast Z3_API Z3_mk_string_to_code(Z3_context c, Z3_ast a)
String to code conversion.
z3py.StrToCode
def StrToCode(s)
Definition: z3py.py:11121

◆ StrToInt()

def z3py.StrToInt (   s) 
Convert string expression to integer
>>> a = StrToInt("1")
>>> simplify(1 == a)
True
>>> b = StrToInt("2")
>>> simplify(1 == b)
False
>>> c = StrToInt(IntToStr(2))
>>> simplify(1 == c)
False

Definition at line 11098 of file z3py.py.

11098 def StrToInt(s):
11099  """Convert string expression to integer
11100  >>> a = StrToInt("1")
11101  >>> simplify(1 == a)
11102  True
11103  >>> b = StrToInt("2")
11104  >>> simplify(1 == b)
11105  False
11106  >>> c = StrToInt(IntToStr(2))
11107  >>> simplify(1 == c)
11108  False
11109  """
11110  s = _coerce_seq(s)
11111  return ArithRef(Z3_mk_str_to_int(s.ctx_ref(), s.as_ast()), s.ctx)
11112 
11113 
Z3_mk_str_to_int
Z3_ast Z3_API Z3_mk_str_to_int(Z3_context c, Z3_ast s)
Convert string to integer.
z3py.StrToInt
def StrToInt(s)
Definition: z3py.py:11098

◆ SubSeq()

def z3py.SubSeq (   s,
  offset,
  length 
) 
Extract substring or subsequence starting at offset

Definition at line 10950 of file z3py.py.

10950 def SubSeq(s, offset, length):
10951  """Extract substring or subsequence starting at offset"""
10952  return Extract(s, offset, length)
10953 
10954 
z3py.SubSeq
def SubSeq(s, offset, length)
Definition: z3py.py:10950

◆ substitute()

def z3py.substitute (   t,
m 
) 
Apply substitution m on t, m is a list of pairs of the form (from, to).
Every occurrence in t of from is replaced with to.

>>> x = Int('x')
>>> y = Int('y')
>>> substitute(x + 1, (x, y + 1))
y + 1 + 1
>>> f = Function('f', IntSort(), IntSort())
>>> substitute(f(x) + f(y), (f(x), IntVal(1)), (f(y), IntVal(1)))
1 + 1

Definition at line 8806 of file z3py.py.

8806 def substitute(t, *m):
8807  """Apply substitution m on t, m is a list of pairs of the form (from, to).
8808  Every occurrence in t of from is replaced with to.
8809 
8810  >>> x = Int('x')
8811  >>> y = Int('y')
8812  >>> substitute(x + 1, (x, y + 1))
8813  y + 1 + 1
8814  >>> f = Function('f', IntSort(), IntSort())
8815  >>> substitute(f(x) + f(y), (f(x), IntVal(1)), (f(y), IntVal(1)))
8816  1 + 1
8817  """
8818  if isinstance(m, tuple):
8819  m1 = _get_args(m)
8820  if isinstance(m1, list) and all(isinstance(p, tuple) for p in m1):
8821  m = m1
8822  if z3_debug():
8823  _z3_assert(is_expr(t), "Z3 expression expected")
8824  _z3_assert(
8825  all([isinstance(p, tuple) and is_expr(p[0]) and is_expr(p[1]) for p in m]),
8826  "Z3 invalid substitution, expression pairs expected.")
8827  _z3_assert(
8828  all([p[0].sort().eq(p[1].sort()) for p in m]),
8829  'Z3 invalid substitution, mismatching "from" and "to" sorts.')
8830  num = len(m)
8831  _from = (Ast * num)()
8832  _to = (Ast * num)()
8833  for i in range(num):
8834  _from[i] = m[i][0].as_ast()
8835  _to[i] = m[i][1].as_ast()
8836  return _to_expr_ref(Z3_substitute(t.ctx.ref(), t.as_ast(), num, _from, _to), t.ctx)
8837 
8838 
Z3_substitute
Z3_ast Z3_API Z3_substitute(Z3_context c, Z3_ast a, unsigned num_exprs, Z3_ast const from[], Z3_ast const to[])
Substitute every occurrence of from[i] in a with to[i], for i smaller than num_exprs....
z3py.substitute
def substitute(t, *m)
Definition: z3py.py:8806

Referenced by Expr< R extends Sort >.substitute().

◆ substitute_funs()

def z3py.substitute_funs (   t,
m 
) 
Apply substitution m on t, m is a list of pairs of a function and expression (from, to)
Every occurrence in to of the function from is replaced with the expression to.
The expression to can have free variables, that refer to the arguments of from.
For examples, see

Definition at line 8859 of file z3py.py.

8859 def substitute_funs(t, *m):
8860  """Apply substitution m on t, m is a list of pairs of a function and expression (from, to)
8861  Every occurrence in to of the function from is replaced with the expression to.
8862  The expression to can have free variables, that refer to the arguments of from.
8863  For examples, see
8864  """
8865  if isinstance(m, tuple):
8866  m1 = _get_args(m)
8867  if isinstance(m1, list) and all(isinstance(p, tuple) for p in m1):
8868  m = m1
8869  if z3_debug():
8870  _z3_assert(is_expr(t), "Z3 expression expected")
8871  _z3_assert(all([isinstance(p, tuple) and is_func_decl(p[0]) and is_expr(p[1]) for p in m]), "Z3 invalid substitution, funcion pairs expected.")
8872  num = len(m)
8873  _from = (FuncDecl * num)()
8874  _to = (Ast * num)()
8875  for i in range(num):
8876  _from[i] = m[i][0].as_func_decl()
8877  _to[i] = m[i][1].as_ast()
8878  return _to_expr_ref(Z3_substitute_funs(t.ctx.ref(), t.as_ast(), num, _from, _to), t.ctx)
8879 
8880 
Z3_substitute_funs
Z3_ast Z3_API Z3_substitute_funs(Z3_context c, Z3_ast a, unsigned num_funs, Z3_func_decl const from[], Z3_ast const to[])
Substitute funcions in from with new expressions in to.
z3py.substitute_funs
def substitute_funs(t, *m)
Definition: z3py.py:8859

◆ substitute_vars()

def z3py.substitute_vars (   t,
m 
) 
Substitute the free variables in t with the expression in m.

>>> v0 = Var(0, IntSort())
>>> v1 = Var(1, IntSort())
>>> x  = Int('x')
>>> f  = Function('f', IntSort(), IntSort(), IntSort())
>>> # replace v0 with x+1 and v1 with x
>>> substitute_vars(f(v0, v1), x + 1, x)
f(x + 1, x)

Definition at line 8839 of file z3py.py.

8839 def substitute_vars(t, *m):
8840  """Substitute the free variables in t with the expression in m.
8841 
8842  >>> v0 = Var(0, IntSort())
8843  >>> v1 = Var(1, IntSort())
8844  >>> x = Int('x')
8845  >>> f = Function('f', IntSort(), IntSort(), IntSort())
8846  >>> # replace v0 with x+1 and v1 with x
8847  >>> substitute_vars(f(v0, v1), x + 1, x)
8848  f(x + 1, x)
8849  """
8850  if z3_debug():
8851  _z3_assert(is_expr(t), "Z3 expression expected")
8852  _z3_assert(all([is_expr(n) for n in m]), "Z3 invalid substitution, list of expressions expected.")
8853  num = len(m)
8854  _to = (Ast * num)()
8855  for i in range(num):
8856  _to[i] = m[i].as_ast()
8857  return _to_expr_ref(Z3_substitute_vars(t.ctx.ref(), t.as_ast(), num, _to), t.ctx)
8858 
Z3_substitute_vars
Z3_ast Z3_API Z3_substitute_vars(Z3_context c, Z3_ast a, unsigned num_exprs, Z3_ast const to[])
Substitute the variables in a with the expressions in to. For every i smaller than num_exprs,...
z3py.substitute_vars
def substitute_vars(t, *m)
Definition: z3py.py:8839

◆ SubString()

def z3py.SubString (   s,
  offset,
  length 
) 
Extract substring or subsequence starting at offset

Definition at line 10945 of file z3py.py.

10945 def SubString(s, offset, length):
10946  """Extract substring or subsequence starting at offset"""
10947  return Extract(s, offset, length)
10948 
10949 
z3py.SubString
def SubString(s, offset, length)
Definition: z3py.py:10945

◆ SuffixOf()

def z3py.SuffixOf (   a,
  b 
) 
Check if 'a' is a suffix of 'b'
>>> s1 = SuffixOf("ab", "abc")
>>> simplify(s1)
False
>>> s2 = SuffixOf("bc", "abc")
>>> simplify(s2)
True

Definition at line 11010 of file z3py.py.

11010 def SuffixOf(a, b):
11011  """Check if 'a' is a suffix of 'b'
11012  >>> s1 = SuffixOf("ab", "abc")
11013  >>> simplify(s1)
11014  False
11015  >>> s2 = SuffixOf("bc", "abc")
11016  >>> simplify(s2)
11017  True
11018  """
11019  ctx = _get_ctx2(a, b)
11020  a = _coerce_seq(a, ctx)
11021  b = _coerce_seq(b, ctx)
11022  return BoolRef(Z3_mk_seq_suffix(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
11023 
11024 
Z3_mk_seq_suffix
Z3_ast Z3_API Z3_mk_seq_suffix(Z3_context c, Z3_ast suffix, Z3_ast s)
Check if suffix is a suffix of s.
z3py.SuffixOf
def SuffixOf(a, b)
Definition: z3py.py:11010

◆ Sum()

def z3py.Sum ( args) 
Create the sum of the Z3 expressions.

>>> a, b, c = Ints('a b c')
>>> Sum(a, b, c)
a + b + c
>>> Sum([a, b, c])
a + b + c
>>> A = IntVector('a', 5)
>>> Sum(A)
a__0 + a__1 + a__2 + a__3 + a__4

Definition at line 8881 of file z3py.py.

8881 def Sum(*args):
8882  """Create the sum of the Z3 expressions.
8883 
8884  >>> a, b, c = Ints('a b c')
8885  >>> Sum(a, b, c)
8886  a + b + c
8887  >>> Sum([a, b, c])
8888  a + b + c
8889  >>> A = IntVector('a', 5)
8890  >>> Sum(A)
8891  a__0 + a__1 + a__2 + a__3 + a__4
8892  """
8893  args = _get_args(args)
8894  if len(args) == 0:
8895  return 0
8896  ctx = _ctx_from_ast_arg_list(args)
8897  if ctx is None:
8898  return _reduce(lambda a, b: a + b, args, 0)
8899  args = _coerce_expr_list(args, ctx)
8900  if is_bv(args[0]):
8901  return _reduce(lambda a, b: a + b, args, 0)
8902  else:
8903  _args, sz = _to_ast_array(args)
8904  return ArithRef(Z3_mk_add(ctx.ref(), sz, _args), ctx)
8905 
8906 
Z3_mk_add
Z3_ast Z3_API Z3_mk_add(Z3_context c, unsigned num_args, Z3_ast const args[])
Create an AST node representing args[0] + ... + args[num_args-1].
z3py.Sum
def Sum(*args)
Definition: z3py.py:8881

◆ tactic_description()

def z3py.tactic_description (   name,
  ctx = None 
) 
Return a short description for the tactic named `name`.

>>> d = tactic_description('simplify')

Definition at line 8460 of file z3py.py.

8460 def tactic_description(name, ctx=None):
8461  """Return a short description for the tactic named `name`.
8462 
8463  >>> d = tactic_description('simplify')
8464  """
8465  ctx = _get_ctx(ctx)
8466  return Z3_tactic_get_descr(ctx.ref(), name)
8467 
8468 
Z3_tactic_get_descr
Z3_string Z3_API Z3_tactic_get_descr(Z3_context c, Z3_string name)
Return a string containing a description of the tactic with the given name.

Referenced by describe_tactics().

◆ tactics()

def z3py.tactics (   ctx = None) 
Return a list of all available tactics in Z3.

>>> l = tactics()
>>> l.count('simplify') == 1
True

Definition at line 8449 of file z3py.py.

8449 def tactics(ctx=None):
8450  """Return a list of all available tactics in Z3.
8451 
8452  >>> l = tactics()
8453  >>> l.count('simplify') == 1
8454  True
8455  """
8456  ctx = _get_ctx(ctx)
8457  return [Z3_get_tactic_name(ctx.ref(), i) for i in range(Z3_get_num_tactics(ctx.ref()))]
8458 
8459 
Z3_get_num_tactics
unsigned Z3_API Z3_get_num_tactics(Z3_context c)
Return the number of builtin tactics available in Z3.
Z3_get_tactic_name
Z3_string Z3_API Z3_get_tactic_name(Z3_context c, unsigned i)
Return the name of the idx tactic.

Referenced by describe_tactics().

◆ Then()

def z3py.Then ( ts,
**  ks 
) 
Return a tactic that applies the tactics in `*ts` in sequence. Shorthand for AndThen(*ts, **ks).

>>> x, y = Ints('x y')
>>> t = Then(Tactic('simplify'), Tactic('solve-eqs'))
>>> t(And(x == 0, y > x + 1))
[[Not(y <= 1)]]
>>> t(And(x == 0, y > x + 1)).as_expr()
Not(y <= 1)

Definition at line 8317 of file z3py.py.

8317 def Then(*ts, **ks):
8318  """Return a tactic that applies the tactics in `*ts` in sequence. Shorthand for AndThen(*ts, **ks).
8319 
8320  >>> x, y = Ints('x y')
8321  >>> t = Then(Tactic('simplify'), Tactic('solve-eqs'))
8322  >>> t(And(x == 0, y > x + 1))
8323  [[Not(y <= 1)]]
8324  >>> t(And(x == 0, y > x + 1)).as_expr()
8325  Not(y <= 1)
8326  """
8327  return AndThen(*ts, **ks)
8328 
8329 
z3py.Then
def Then(*ts, **ks)
Definition: z3py.py:8317

◆ to_Ast()

def z3py.to_Ast (   ptr)

Definition at line 11329 of file z3py.py.

11329 def to_Ast(ptr,):
11330  ast = Ast(ptr)
11331  super(ctypes.c_void_p, ast).__init__(ptr)
11332  return ast
11333 

Referenced by on_clause_eh(), user_prop_created(), user_prop_decide(), user_prop_diseq(), user_prop_eq(), and user_prop_fixed().

◆ to_AstVectorObj()

def z3py.to_AstVectorObj (   ptr)

Definition at line 11339 of file z3py.py.

11339 def to_AstVectorObj(ptr,):
11340  v = AstVectorObj(ptr)
11341  super(ctypes.c_void_p, v).__init__(ptr)
11342  return v
11343 
11344 # NB. my-hacky-class only works for a single instance of OnClause
11345 # it should be replaced with a proper correlation between OnClause
11346 # and object references that can be passed over the FFI.
11347 # for UserPropagator we use a global dictionary, which isn't great code.
11348 

Referenced by on_clause_eh().

◆ to_ContextObj()

def z3py.to_ContextObj (   ptr)

Definition at line 11334 of file z3py.py.

11334 def to_ContextObj(ptr,):
11335  ctx = ContextObj(ptr)
11336  super(ctypes.c_void_p, ctx).__init__(ptr)
11337  return ctx
11338 
z3py.to_ContextObj
def to_ContextObj(ptr)
Definition: z3py.py:11334

Referenced by user_prop_fresh().

◆ to_symbol()

def z3py.to_symbol (   s,
  ctx = None 
) 
Convert an integer or string into a Z3 symbol.

Definition at line 124 of file z3py.py.

124 def to_symbol(s, ctx=None):
125  """Convert an integer or string into a Z3 symbol."""
126  if _is_int(s):
127  return Z3_mk_int_symbol(_get_ctx(ctx).ref(), s)
128  else:
129  return Z3_mk_string_symbol(_get_ctx(ctx).ref(), s)
130 
131 
Z3_mk_string_symbol
Z3_symbol Z3_API Z3_mk_string_symbol(Z3_context c, Z3_string s)
Create a Z3 symbol using a C string.
Z3_mk_int_symbol
Z3_symbol Z3_API Z3_mk_int_symbol(Z3_context c, int i)
Create a Z3 symbol using an integer.

Referenced by Fixedpoint.add_rule(), Optimize.add_soft(), Array(), BitVec(), Bool(), Const(), CreateDatatypes(), DatatypeSort(), DeclareSort(), EnumSort(), FiniteDomainSort(), FP(), Function(), ParamDescrsRef.get_documentation(), ParamDescrsRef.get_kind(), Int(), is_quantifier(), PropagateFunction(), prove(), Real(), RecFunction(), ParamsRef.set(), Fixedpoint.set_predicate_representation(), SolverFor(), String(), and Fixedpoint.update_rule().

◆ ToInt()

def z3py.ToInt (   a) 
 Return the Z3 expression ToInt(a).

>>> x = Real('x')
>>> x.sort()
Real
>>> n = ToInt(x)
>>> n
ToInt(x)
>>> n.sort()
Int

Definition at line 3376 of file z3py.py.

3376 def ToInt(a):
3377  """ Return the Z3 expression ToInt(a).
3378 
3379  >>> x = Real('x')
3380  >>> x.sort()
3381  Real
3382  >>> n = ToInt(x)
3383  >>> n
3384  ToInt(x)
3385  >>> n.sort()
3386  Int
3387  """
3388  if z3_debug():
3389  _z3_assert(a.is_real(), "Z3 real expression expected.")
3390  ctx = a.ctx
3391  return ArithRef(Z3_mk_real2int(ctx.ref(), a.as_ast()), ctx)
3392 
3393 
Z3_mk_real2int
Z3_ast Z3_API Z3_mk_real2int(Z3_context c, Z3_ast t1)
Coerce a real to an integer.
z3py.ToInt
def ToInt(a)
Definition: z3py.py:3376

◆ ToReal()

def z3py.ToReal (   a) 
 Return the Z3 expression ToReal(a).

>>> x = Int('x')
>>> x.sort()
Int
>>> n = ToReal(x)
>>> n
ToReal(x)
>>> n.sort()
Real

Definition at line 3358 of file z3py.py.

3358 def ToReal(a):
3359  """ Return the Z3 expression ToReal(a).
3360 
3361  >>> x = Int('x')
3362  >>> x.sort()
3363  Int
3364  >>> n = ToReal(x)
3365  >>> n
3366  ToReal(x)
3367  >>> n.sort()
3368  Real
3369  """
3370  if z3_debug():
3371  _z3_assert(a.is_int(), "Z3 integer expression expected.")
3372  ctx = a.ctx
3373  return ArithRef(Z3_mk_int2real(ctx.ref(), a.as_ast()), ctx)
3374 
3375 
Z3_mk_int2real
Z3_ast Z3_API Z3_mk_int2real(Z3_context c, Z3_ast t1)
Coerce an integer to a real.
z3py.ToReal
def ToReal(a)
Definition: z3py.py:3358

◆ TransitiveClosure()

def z3py.TransitiveClosure (   f) 
Given a binary relation R, such that the two arguments have the same sort
create the transitive closure relation R+.
The transitive closure R+ is a new relation.

Definition at line 11322 of file z3py.py.

11322 def TransitiveClosure(f):
11323  """Given a binary relation R, such that the two arguments have the same sort
11324  create the transitive closure relation R+.
11325  The transitive closure R+ is a new relation.
11326  """
11327  return FuncDeclRef(Z3_mk_transitive_closure(f.ctx_ref(), f.ast), f.ctx)
11328 
Z3_mk_transitive_closure
Z3_func_decl Z3_API Z3_mk_transitive_closure(Z3_context c, Z3_func_decl f)
create transitive closure of binary relation.
z3py.TransitiveClosure
def TransitiveClosure(f)
Definition: z3py.py:11322

◆ TreeOrder()

def z3py.TreeOrder (   a,
  index 
)

Definition at line 11314 of file z3py.py.

11314 def TreeOrder(a, index):
11315  return FuncDeclRef(Z3_mk_tree_order(a.ctx_ref(), a.ast, index), a.ctx)
11316 
11317 
Z3_mk_tree_order
Z3_func_decl Z3_API Z3_mk_tree_order(Z3_context c, Z3_sort a, unsigned id)
create a tree ordering relation over signature a identified using index id.
z3py.TreeOrder
def TreeOrder(a, index)
Definition: z3py.py:11314

◆ TryFor()

def z3py.TryFor (   t,
  ms,
  ctx = None 
) 
Return a tactic that applies `t` to a given goal for `ms` milliseconds.

If `t` does not terminate in `ms` milliseconds, then it fails.

Definition at line 8440 of file z3py.py.

8440 def TryFor(t, ms, ctx=None):
8441  """Return a tactic that applies `t` to a given goal for `ms` milliseconds.
8442 
8443  If `t` does not terminate in `ms` milliseconds, then it fails.
8444  """
8445  t = _to_tactic(t, ctx)
8446  return Tactic(Z3_tactic_try_for(t.ctx.ref(), t.tactic, ms), t.ctx)
8447 
8448 
Z3_tactic_try_for
Z3_tactic Z3_API Z3_tactic_try_for(Z3_context c, Z3_tactic t, unsigned ms)
Return a tactic that applies t to a given goal for ms milliseconds. If t does not terminate in ms mil...
z3py.TryFor
def TryFor(t, ms, ctx=None)
Definition: z3py.py:8440

◆ TupleSort()

def z3py.TupleSort (   name,
  sorts,
  ctx = None 
) 
Create a named tuple sort base on a set of underlying sorts
Example:
    >>> pair, mk_pair, (first, second) = TupleSort("pair", [IntSort(), StringSort()])

Definition at line 5363 of file z3py.py.

5363 def TupleSort(name, sorts, ctx=None):
5364  """Create a named tuple sort base on a set of underlying sorts
5365  Example:
5366  >>> pair, mk_pair, (first, second) = TupleSort("pair", [IntSort(), StringSort()])
5367  """
5368  tuple = Datatype(name, ctx)
5369  projects = [("project%d" % i, sorts[i]) for i in range(len(sorts))]
5370  tuple.declare(name, *projects)
5371  tuple = tuple.create()
5372  return tuple, tuple.constructor(0), [tuple.accessor(0, i) for i in range(len(sorts))]
5373 
5374 
z3py.TupleSort
def TupleSort(name, sorts, ctx=None)
Definition: z3py.py:5363

Referenced by Context.MkTupleSort(), and Context.mkTupleSort().

◆ UDiv()

def z3py.UDiv (   a,
  b 
) 
Create the Z3 expression (unsigned) division `self / other`.

Use the operator / for signed division.

>>> x = BitVec('x', 32)
>>> y = BitVec('y', 32)
>>> UDiv(x, y)
UDiv(x, y)
>>> UDiv(x, y).sort()
BitVec(32)
>>> (x / y).sexpr()
'(bvsdiv x y)'
>>> UDiv(x, y).sexpr()
'(bvudiv x y)'

Definition at line 4236 of file z3py.py.

4236 def UDiv(a, b):
4237  """Create the Z3 expression (unsigned) division `self / other`.
4238 
4239  Use the operator / for signed division.
4240 
4241  >>> x = BitVec('x', 32)
4242  >>> y = BitVec('y', 32)
4243  >>> UDiv(x, y)
4244  UDiv(x, y)
4245  >>> UDiv(x, y).sort()
4246  BitVec(32)
4247  >>> (x / y).sexpr()
4248  '(bvsdiv x y)'
4249  >>> UDiv(x, y).sexpr()
4250  '(bvudiv x y)'
4251  """
4252  _check_bv_args(a, b)
4253  a, b = _coerce_exprs(a, b)
4254  return BitVecRef(Z3_mk_bvudiv(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4255 
4256 
Z3_mk_bvudiv
Z3_ast Z3_API Z3_mk_bvudiv(Z3_context c, Z3_ast t1, Z3_ast t2)
Unsigned division.
z3py.UDiv
def UDiv(a, b)
Definition: z3py.py:4236

◆ UGE()

def z3py.UGE (   a,
  b 
) 
Create the Z3 expression (unsigned) `other >= self`.

Use the operator >= for signed greater than or equal to.

>>> x, y = BitVecs('x y', 32)
>>> UGE(x, y)
UGE(x, y)
>>> (x >= y).sexpr()
'(bvsge x y)'
>>> UGE(x, y).sexpr()
'(bvuge x y)'

Definition at line 4200 of file z3py.py.

4200 def UGE(a, b):
4201  """Create the Z3 expression (unsigned) `other >= self`.
4202 
4203  Use the operator >= for signed greater than or equal to.
4204 
4205  >>> x, y = BitVecs('x y', 32)
4206  >>> UGE(x, y)
4207  UGE(x, y)
4208  >>> (x >= y).sexpr()
4209  '(bvsge x y)'
4210  >>> UGE(x, y).sexpr()
4211  '(bvuge x y)'
4212  """
4213  _check_bv_args(a, b)
4214  a, b = _coerce_exprs(a, b)
4215  return BoolRef(Z3_mk_bvuge(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4216 
4217 
Z3_mk_bvuge
Z3_ast Z3_API Z3_mk_bvuge(Z3_context c, Z3_ast t1, Z3_ast t2)
Unsigned greater than or equal to.
z3py.UGE
def UGE(a, b)
Definition: z3py.py:4200

◆ UGT()

def z3py.UGT (   a,
  b 
) 
Create the Z3 expression (unsigned) `other > self`.

Use the operator > for signed greater than.

>>> x, y = BitVecs('x y', 32)
>>> UGT(x, y)
UGT(x, y)
>>> (x > y).sexpr()
'(bvsgt x y)'
>>> UGT(x, y).sexpr()
'(bvugt x y)'

Definition at line 4218 of file z3py.py.

4218 def UGT(a, b):
4219  """Create the Z3 expression (unsigned) `other > self`.
4220 
4221  Use the operator > for signed greater than.
4222 
4223  >>> x, y = BitVecs('x y', 32)
4224  >>> UGT(x, y)
4225  UGT(x, y)
4226  >>> (x > y).sexpr()
4227  '(bvsgt x y)'
4228  >>> UGT(x, y).sexpr()
4229  '(bvugt x y)'
4230  """
4231  _check_bv_args(a, b)
4232  a, b = _coerce_exprs(a, b)
4233  return BoolRef(Z3_mk_bvugt(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4234 
4235 
Z3_mk_bvugt
Z3_ast Z3_API Z3_mk_bvugt(Z3_context c, Z3_ast t1, Z3_ast t2)
Unsigned greater than.
z3py.UGT
def UGT(a, b)
Definition: z3py.py:4218

◆ ULE()

def z3py.ULE (   a,
  b 
) 
Create the Z3 expression (unsigned) `other <= self`.

Use the operator <= for signed less than or equal to.

>>> x, y = BitVecs('x y', 32)
>>> ULE(x, y)
ULE(x, y)
>>> (x <= y).sexpr()
'(bvsle x y)'
>>> ULE(x, y).sexpr()
'(bvule x y)'

Definition at line 4164 of file z3py.py.

4164 def ULE(a, b):
4165  """Create the Z3 expression (unsigned) `other <= self`.
4166 
4167  Use the operator <= for signed less than or equal to.
4168 
4169  >>> x, y = BitVecs('x y', 32)
4170  >>> ULE(x, y)
4171  ULE(x, y)
4172  >>> (x <= y).sexpr()
4173  '(bvsle x y)'
4174  >>> ULE(x, y).sexpr()
4175  '(bvule x y)'
4176  """
4177  _check_bv_args(a, b)
4178  a, b = _coerce_exprs(a, b)
4179  return BoolRef(Z3_mk_bvule(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4180 
4181 
Z3_mk_bvule
Z3_ast Z3_API Z3_mk_bvule(Z3_context c, Z3_ast t1, Z3_ast t2)
Unsigned less than or equal to.
z3py.ULE
def ULE(a, b)
Definition: z3py.py:4164

◆ ULT()

def z3py.ULT (   a,
  b 
) 
Create the Z3 expression (unsigned) `other < self`.

Use the operator < for signed less than.

>>> x, y = BitVecs('x y', 32)
>>> ULT(x, y)
ULT(x, y)
>>> (x < y).sexpr()
'(bvslt x y)'
>>> ULT(x, y).sexpr()
'(bvult x y)'

Definition at line 4182 of file z3py.py.

4182 def ULT(a, b):
4183  """Create the Z3 expression (unsigned) `other < self`.
4184 
4185  Use the operator < for signed less than.
4186 
4187  >>> x, y = BitVecs('x y', 32)
4188  >>> ULT(x, y)
4189  ULT(x, y)
4190  >>> (x < y).sexpr()
4191  '(bvslt x y)'
4192  >>> ULT(x, y).sexpr()
4193  '(bvult x y)'
4194  """
4195  _check_bv_args(a, b)
4196  a, b = _coerce_exprs(a, b)
4197  return BoolRef(Z3_mk_bvult(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4198 
4199 
Z3_mk_bvult
Z3_ast Z3_API Z3_mk_bvult(Z3_context c, Z3_ast t1, Z3_ast t2)
Unsigned less than.
z3py.ULT
def ULT(a, b)
Definition: z3py.py:4182

◆ Union()

def z3py.Union ( args) 
Create union of regular expressions.
>>> re = Union(Re("a"), Re("b"), Re("c"))
>>> print (simplify(InRe("d", re)))
False

Definition at line 11186 of file z3py.py.

11186 def Union(*args):
11187  """Create union of regular expressions.
11188  >>> re = Union(Re("a"), Re("b"), Re("c"))
11189  >>> print (simplify(InRe("d", re)))
11190  False
11191  """
11192  args = _get_args(args)
11193  sz = len(args)
11194  if z3_debug():
11195  _z3_assert(sz > 0, "At least one argument expected.")
11196  _z3_assert(all([is_re(a) for a in args]), "All arguments must be regular expressions.")
11197  if sz == 1:
11198  return args[0]
11199  ctx = args[0].ctx
11200  v = (Ast * sz)()
11201  for i in range(sz):
11202  v[i] = args[i].as_ast()
11203  return ReRef(Z3_mk_re_union(ctx.ref(), sz, v), ctx)
11204 
11205 
Z3_mk_re_union
Z3_ast Z3_API Z3_mk_re_union(Z3_context c, unsigned n, Z3_ast const args[])
Create the union of the regular languages.
z3py.Union
def Union(*args)
Definition: z3py.py:11186

Referenced by ReRef.__add__().

◆ Unit()

def z3py.Unit (   a) 
Create a singleton sequence

Definition at line 10990 of file z3py.py.

10990 def Unit(a):
10991  """Create a singleton sequence"""
10992  return SeqRef(Z3_mk_seq_unit(a.ctx_ref(), a.as_ast()), a.ctx)
10993 
10994 
Z3_mk_seq_unit
Z3_ast Z3_API Z3_mk_seq_unit(Z3_context c, Z3_ast a)
Create a unit sequence of a.
z3py.Unit
def Unit(a)
Definition: z3py.py:10990

◆ Update()

def z3py.Update (   a,
args 
) 
Return a Z3 store array expression.

>>> a    = Array('a', IntSort(), IntSort())
>>> i, v = Ints('i v')
>>> s    = Update(a, i, v)
>>> s.sort()
Array(Int, Int)
>>> prove(s[i] == v)
proved
>>> j    = Int('j')
>>> prove(Implies(i != j, s[j] == a[j]))
proved

Definition at line 4747 of file z3py.py.

4747 def Update(a, *args):
4748  """Return a Z3 store array expression.
4749 
4750  >>> a = Array('a', IntSort(), IntSort())
4751  >>> i, v = Ints('i v')
4752  >>> s = Update(a, i, v)
4753  >>> s.sort()
4754  Array(Int, Int)
4755  >>> prove(s[i] == v)
4756  proved
4757  >>> j = Int('j')
4758  >>> prove(Implies(i != j, s[j] == a[j]))
4759  proved
4760  """
4761  if z3_debug():
4762  _z3_assert(is_array_sort(a), "First argument must be a Z3 array expression")
4763  args = _get_args(args)
4764  ctx = a.ctx
4765  if len(args) <= 1:
4766  raise Z3Exception("array update requires index and value arguments")
4767  if len(args) == 2:
4768  i = args[0]
4769  v = args[1]
4770  i = a.sort().domain().cast(i)
4771  v = a.sort().range().cast(v)
4772  return _to_expr_ref(Z3_mk_store(ctx.ref(), a.as_ast(), i.as_ast(), v.as_ast()), ctx)
4773  v = a.sort().range().cast(args[-1])
4774  idxs = [a.sort().domain_n(i).cast(args[i]) for i in range(len(args)-1)]
4775  _args, sz = _to_ast_array(idxs)
4776  return _to_expr_ref(Z3_mk_store_n(ctx.ref(), a.as_ast(), sz, _args, v.as_ast()), ctx)
4777 
4778 
Z3_mk_store
Z3_ast Z3_API Z3_mk_store(Z3_context c, Z3_ast a, Z3_ast i, Z3_ast v)
Array update.
Z3_mk_store_n
Z3_ast Z3_API Z3_mk_store_n(Z3_context c, Z3_ast a, unsigned n, Z3_ast const *idxs, Z3_ast v)
n-ary Array update.

Referenced by Store().

◆ URem()

def z3py.URem (   a,
  b 
) 
Create the Z3 expression (unsigned) remainder `self % other`.

Use the operator % for signed modulus, and SRem() for signed remainder.

>>> x = BitVec('x', 32)
>>> y = BitVec('y', 32)
>>> URem(x, y)
URem(x, y)
>>> URem(x, y).sort()
BitVec(32)
>>> (x % y).sexpr()
'(bvsmod x y)'
>>> URem(x, y).sexpr()
'(bvurem x y)'

Definition at line 4257 of file z3py.py.

4257 def URem(a, b):
4258  """Create the Z3 expression (unsigned) remainder `self % other`.
4259 
4260  Use the operator % for signed modulus, and SRem() for signed remainder.
4261 
4262  >>> x = BitVec('x', 32)
4263  >>> y = BitVec('y', 32)
4264  >>> URem(x, y)
4265  URem(x, y)
4266  >>> URem(x, y).sort()
4267  BitVec(32)
4268  >>> (x % y).sexpr()
4269  '(bvsmod x y)'
4270  >>> URem(x, y).sexpr()
4271  '(bvurem x y)'
4272  """
4273  _check_bv_args(a, b)
4274  a, b = _coerce_exprs(a, b)
4275  return BitVecRef(Z3_mk_bvurem(a.ctx_ref(), a.as_ast(), b.as_ast()), a.ctx)
4276 
4277 
Z3_mk_bvurem
Z3_ast Z3_API Z3_mk_bvurem(Z3_context c, Z3_ast t1, Z3_ast t2)
Unsigned remainder.
z3py.URem
def URem(a, b)
Definition: z3py.py:4257

◆ user_prop_created()

def z3py.user_prop_created (   ctx,
  cb,
  id 
)

Definition at line 11448 of file z3py.py.

11448 def user_prop_created(ctx, cb, id):
11449  prop = _prop_closures.get(ctx)
11450  prop.cb = cb
11451  id = _to_expr_ref(to_Ast(id), prop.ctx())
11452  prop.created(id)
11453  prop.cb = None
11454 
z3py.user_prop_created
def user_prop_created(ctx, cb, id)
Definition: z3py.py:11448

◆ user_prop_decide()

def z3py.user_prop_decide (   ctx,
  cb,
  t_ref,
  idx_ref,
  phase_ref 
)

Definition at line 11479 of file z3py.py.

11479 def user_prop_decide(ctx, cb, t_ref, idx_ref, phase_ref):
11480  prop = _prop_closures.get(ctx)
11481  prop.cb = cb
11482  t = _to_expr_ref(to_Ast(t_ref), prop.ctx())
11483  t, idx, phase = prop.decide(t, idx, phase)
11484  t_ref = t
11485  idx_ref = idx
11486  phase_ref = phase
11487  prop.cb = None
11488 
11489 
z3py.user_prop_decide
def user_prop_decide(ctx, cb, t_ref, idx_ref, phase_ref)
Definition: z3py.py:11479

◆ user_prop_diseq()

def z3py.user_prop_diseq (   ctx,
  cb,
  x,
  y 
)

Definition at line 11469 of file z3py.py.

11469 def user_prop_diseq(ctx, cb, x, y):
11470  prop = _prop_closures.get(ctx)
11471  prop.cb = cb
11472  x = _to_expr_ref(to_Ast(x), prop.ctx())
11473  y = _to_expr_ref(to_Ast(y), prop.ctx())
11474  prop.diseq(x, y)
11475  prop.cb = None
11476 
11477 # TODO The decision callback is not fully implemented.
11478 # It needs to handle the ast*, unsigned* idx, and Z3_lbool*
z3py.user_prop_diseq
def user_prop_diseq(ctx, cb, x, y)
Definition: z3py.py:11469

◆ user_prop_eq()

def z3py.user_prop_eq (   ctx,
  cb,
  x,
  y 
)

Definition at line 11461 of file z3py.py.

11461 def user_prop_eq(ctx, cb, x, y):
11462  prop = _prop_closures.get(ctx)
11463  prop.cb = cb
11464  x = _to_expr_ref(to_Ast(x), prop.ctx())
11465  y = _to_expr_ref(to_Ast(y), prop.ctx())
11466  prop.eq(x, y)
11467  prop.cb = None
11468 
z3py.user_prop_eq
def user_prop_eq(ctx, cb, x, y)
Definition: z3py.py:11461

◆ user_prop_final()

def z3py.user_prop_final (   ctx,
  cb 
)

Definition at line 11455 of file z3py.py.

11455 def user_prop_final(ctx, cb):
11456  prop = _prop_closures.get(ctx)
11457  prop.cb = cb
11458  prop.final()
11459  prop.cb = None
11460 
z3py.user_prop_final
def user_prop_final(ctx, cb)
Definition: z3py.py:11455

◆ user_prop_fixed()

def z3py.user_prop_fixed (   ctx,
  cb,
  id,
  value 
)

Definition at line 11440 of file z3py.py.

11440 def user_prop_fixed(ctx, cb, id, value):
11441  prop = _prop_closures.get(ctx)
11442  prop.cb = cb
11443  id = _to_expr_ref(to_Ast(id), prop.ctx())
11444  value = _to_expr_ref(to_Ast(value), prop.ctx())
11445  prop.fixed(id, value)
11446  prop.cb = None
11447 
z3py.user_prop_fixed
def user_prop_fixed(ctx, cb, id, value)
Definition: z3py.py:11440

◆ user_prop_fresh()

def z3py.user_prop_fresh (   ctx,
  _new_ctx 
)

Definition at line 11426 of file z3py.py.

11426 def user_prop_fresh(ctx, _new_ctx):
11427  _prop_closures.set_threaded()
11428  prop = _prop_closures.get(ctx)
11429  nctx = Context()
11430  Z3_del_context(nctx.ctx)
11431  new_ctx = to_ContextObj(_new_ctx)
11432  nctx.ctx = new_ctx
11433  nctx.eh = Z3_set_error_handler(new_ctx, z3_error_handler)
11434  nctx.owner = False
11435  new_prop = prop.fresh(nctx)
11436  _prop_closures.set(new_prop.id, new_prop)
11437  return new_prop.id
11438 
11439 
Z3_del_context
void Z3_API Z3_del_context(Z3_context c)
Delete the given logical context.
Z3_set_error_handler
void Z3_API Z3_set_error_handler(Z3_context c, Z3_error_handler h)
Register a Z3 error handler.
z3py.user_prop_fresh
def user_prop_fresh(ctx, _new_ctx)
Definition: z3py.py:11426

◆ user_prop_pop()

def z3py.user_prop_pop (   ctx,
  cb,
  num_scopes 
)

Definition at line 11420 of file z3py.py.

11420 def user_prop_pop(ctx, cb, num_scopes):
11421  prop = _prop_closures.get(ctx)
11422  prop.cb = cb
11423  prop.pop(num_scopes)
11424 
11425 
z3py.user_prop_pop
def user_prop_pop(ctx, cb, num_scopes)
Definition: z3py.py:11420

◆ user_prop_push()

def z3py.user_prop_push (   ctx,
  cb 
)

Definition at line 11414 of file z3py.py.

11414 def user_prop_push(ctx, cb):
11415  prop = _prop_closures.get(ctx)
11416  prop.cb = cb
11417  prop.push()
11418 
11419 
z3py.user_prop_push
def user_prop_push(ctx, cb)
Definition: z3py.py:11414

◆ Var()

def z3py.Var (   idx,
  s 
) 
Create a Z3 free variable. Free variables are used to create quantified formulas.
A free variable with index n is bound when it occurs within the scope of n+1 quantified
declarations.

>>> Var(0, IntSort())
Var(0)
>>> eq(Var(0, IntSort()), Var(0, BoolSort()))
False

Definition at line 1470 of file z3py.py.

1470 def Var(idx, s):
1471  """Create a Z3 free variable. Free variables are used to create quantified formulas.
1472  A free variable with index n is bound when it occurs within the scope of n+1 quantified
1473  declarations.
1474 
1475  >>> Var(0, IntSort())
1476  Var(0)
1477  >>> eq(Var(0, IntSort()), Var(0, BoolSort()))
1478  False
1479  """
1480  if z3_debug():
1481  _z3_assert(is_sort(s), "Z3 sort expected")
1482  return _to_expr_ref(Z3_mk_bound(s.ctx_ref(), idx, s.ast), s.ctx)
1483 
1484 
Z3_mk_bound
Z3_ast Z3_API Z3_mk_bound(Z3_context c, unsigned index, Z3_sort ty)
Create a variable.

Referenced by RealVar().

◆ When()

def z3py.When (   p,
  t,
  ctx = None 
) 
Return a tactic that applies tactic `t` only if probe `p` evaluates to true.
Otherwise, it returns the input goal unmodified.

>>> t = When(Probe('size') > 2, Tactic('simplify'))
>>> x, y = Ints('x y')
>>> g = Goal()
>>> g.add(x > 0)
>>> g.add(y > 0)
>>> t(g)
[[x > 0, y > 0]]
>>> g.add(x == y + 1)
>>> t(g)
[[Not(x <= 0), Not(y <= 0), x == 1 + y]]

Definition at line 8734 of file z3py.py.

8734 def When(p, t, ctx=None):
8735  """Return a tactic that applies tactic `t` only if probe `p` evaluates to true.
8736  Otherwise, it returns the input goal unmodified.
8737 
8738  >>> t = When(Probe('size') > 2, Tactic('simplify'))
8739  >>> x, y = Ints('x y')
8740  >>> g = Goal()
8741  >>> g.add(x > 0)
8742  >>> g.add(y > 0)
8743  >>> t(g)
8744  [[x > 0, y > 0]]
8745  >>> g.add(x == y + 1)
8746  >>> t(g)
8747  [[Not(x <= 0), Not(y <= 0), x == 1 + y]]
8748  """
8749  p = _to_probe(p, ctx)
8750  t = _to_tactic(t, ctx)
8751  return Tactic(Z3_tactic_when(t.ctx.ref(), p.probe, t.tactic), t.ctx)
8752 
8753 
Z3_tactic_when
Z3_tactic Z3_API Z3_tactic_when(Z3_context c, Z3_probe p, Z3_tactic t)
Return a tactic that applies t to a given goal is the probe p evaluates to true. If p evaluates to fa...
z3py.When
def When(p, t, ctx=None)
Definition: z3py.py:8734

◆ With()

def z3py.With (   t,
args,
**  keys 
) 
Return a tactic that applies tactic `t` using the given configuration options.

>>> x, y = Ints('x y')
>>> t = With(Tactic('simplify'), som=True)
>>> t((x + 1)*(y + 2) == 0)
[[2*x + y + x*y == -2]]

Definition at line 8391 of file z3py.py.

8391 def With(t, *args, **keys):
8392  """Return a tactic that applies tactic `t` using the given configuration options.
8393 
8394  >>> x, y = Ints('x y')
8395  >>> t = With(Tactic('simplify'), som=True)
8396  >>> t((x + 1)*(y + 2) == 0)
8397  [[2*x + y + x*y == -2]]
8398  """
8399  ctx = keys.pop("ctx", None)
8400  t = _to_tactic(t, ctx)
8401  p = args2params(args, keys, t.ctx)
8402  return Tactic(Z3_tactic_using_params(t.ctx.ref(), t.tactic, p.params), t.ctx)
8403 
8404 
Z3_tactic_using_params
Z3_tactic Z3_API Z3_tactic_using_params(Z3_context c, Z3_tactic t, Z3_params p)
Return a tactic that applies t using the given set of parameters.
z3py.With
def With(t, *args, **keys)
Definition: z3py.py:8391

◆ WithParams()

def z3py.WithParams (   t,
  p 
) 
Return a tactic that applies tactic `t` using the given configuration options.

>>> x, y = Ints('x y')
>>> p = ParamsRef()
>>> p.set("som", True)
>>> t = WithParams(Tactic('simplify'), p)
>>> t((x + 1)*(y + 2) == 0)
[[2*x + y + x*y == -2]]

Definition at line 8405 of file z3py.py.

8405 def WithParams(t, p):
8406  """Return a tactic that applies tactic `t` using the given configuration options.
8407 
8408  >>> x, y = Ints('x y')
8409  >>> p = ParamsRef()
8410  >>> p.set("som", True)
8411  >>> t = WithParams(Tactic('simplify'), p)
8412  >>> t((x + 1)*(y + 2) == 0)
8413  [[2*x + y + x*y == -2]]
8414  """
8415  t = _to_tactic(t, None)
8416  return Tactic(Z3_tactic_using_params(t.ctx.ref(), t.tactic, p.params), t.ctx)
8417 
8418 
z3py.WithParams
def WithParams(t, p)
Definition: z3py.py:8405

◆ Xor()

def z3py.Xor (   a,
  b,
  ctx = None 
) 
Create a Z3 Xor expression.

>>> p, q = Bools('p q')
>>> Xor(p, q)
Xor(p, q)
>>> simplify(Xor(p, q))
Not(p == q)

Definition at line 1799 of file z3py.py.

1799 def Xor(a, b, ctx=None):
1800  """Create a Z3 Xor expression.
1801 
1802  >>> p, q = Bools('p q')
1803  >>> Xor(p, q)
1804  Xor(p, q)
1805  >>> simplify(Xor(p, q))
1806  Not(p == q)
1807  """
1808  ctx = _get_ctx(_ctx_from_ast_arg_list([a, b], ctx))
1809  s = BoolSort(ctx)
1810  a = s.cast(a)
1811  b = s.cast(b)
1812  return BoolRef(Z3_mk_xor(ctx.ref(), a.as_ast(), b.as_ast()), ctx)
1813 
1814 
Z3_mk_xor
Z3_ast Z3_API Z3_mk_xor(Z3_context c, Z3_ast t1, Z3_ast t2)
Create an AST node representing t1 xor t2.
z3py.Xor
def Xor(a, b, ctx=None)
Definition: z3py.py:1799

◆ z3_debug()

def z3py.z3_debug ( )

Definition at line 62 of file z3py.py.

62 def z3_debug():
63  global Z3_DEBUG
64  return Z3_DEBUG
65 
66 

Referenced by FuncDeclRef.__call__(), Probe.__call__(), QuantifierRef.__getitem__(), ModelRef.__getitem__(), Context.__init__(), Goal.__init__(), ArithRef.__mod__(), ArithRef.__rmod__(), DatatypeSortRef.accessor(), And(), AndThen(), Tactic.apply(), ExprRef.arg(), args2params(), ArraySort(), IntNumRef.as_long(), AtLeast(), AtMost(), BV2Int(), BVRedAnd(), BVRedOr(), BVSNegNoOverflow(), SortRef.cast(), BoolSortRef.cast(), ArithSortRef.cast(), BitVecSortRef.cast(), FPSortRef.cast(), Concat(), Const(), DatatypeSortRef.constructor(), Goal.convert_model(), CreateDatatypes(), ExprRef.decl(), Datatype.declare(), Datatype.declare_core(), Default(), describe_probes(), deserialize(), Distinct(), FuncDeclRef.domain(), EnumSort(), eq(), AstRef.eq(), Ext(), Extract(), FiniteDomainVal(), fpIsPositive(), fpNeg(), FPSort(), fpToFPUnsigned(), fpToIEEEBV(), fpToReal(), fpToSBV(), fpToUBV(), FreshFunction(), Function(), get_as_array_func(), ModelRef.get_interp(), get_map_func(), ModelRef.get_universe(), get_var_index(), If(), AlgebraicNumRef.index(), Intersect(), is_quantifier(), is_sort(), IsInt(), K(), Map(), MultiPattern(), QuantifierRef.no_pattern(), ExprRef.num_args(), Or(), OrElse(), Tactic.param_descrs(), ParOr(), ParThen(), QuantifierRef.pattern(), PropagateFunction(), prove(), RatVal(), RealSort(), RecFunction(), DatatypeSortRef.recognizer(), RepeatBitVec(), Select(), ParamsRef.set(), set_param(), SignExt(), simplify(), solve_using(), substitute(), substitute_funs(), substitute_vars(), ToInt(), ToReal(), AstRef.translate(), Goal.translate(), ModelRef.translate(), Solver.translate(), Union(), Update(), Var(), QuantifierRef.var_name(), QuantifierRef.var_sort(), and ZeroExt().

◆ z3_error_handler()

def z3py.z3_error_handler (   c,
  e 
)

Definition at line 174 of file z3py.py.

174 def z3_error_handler(c, e):
175  # Do nothing error handler, just avoid exit(0)
176  # The wrappers in z3core.py will raise a Z3Exception if an error is detected
177  return
178 
179 
z3py.z3_error_handler
def z3_error_handler(c, e)
Definition: z3py.py:174

◆ ZeroExt()

def z3py.ZeroExt (   n,
  a 
) 
Return a bit-vector expression with `n` extra zero-bits.

>>> x = BitVec('x', 16)
>>> n = ZeroExt(8, x)
>>> n.size()
24
>>> n
ZeroExt(8, x)
>>> n.sort()
BitVec(24)
>>> v0 = BitVecVal(2, 2)
>>> v0
2
>>> v0.size()
2
>>> v  = simplify(ZeroExt(6, v0))
>>> v
2
>>> v.size()
8

Definition at line 4393 of file z3py.py.

4393 def ZeroExt(n, a):
4394  """Return a bit-vector expression with `n` extra zero-bits.
4395 
4396  >>> x = BitVec('x', 16)
4397  >>> n = ZeroExt(8, x)
4398  >>> n.size()
4399  24
4400  >>> n
4401  ZeroExt(8, x)
4402  >>> n.sort()
4403  BitVec(24)
4404  >>> v0 = BitVecVal(2, 2)
4405  >>> v0
4406  2
4407  >>> v0.size()
4408  2
4409  >>> v = simplify(ZeroExt(6, v0))
4410  >>> v
4411  2
4412  >>> v.size()
4413  8
4414  """
4415  if z3_debug():
4416  _z3_assert(_is_int(n), "First argument must be an integer")
4417  _z3_assert(is_bv(a), "Second argument must be a Z3 bit-vector expression")
4418  return BitVecRef(Z3_mk_zero_ext(a.ctx_ref(), n, a.as_ast()), a.ctx)
4419 
4420 
Z3_mk_zero_ext
Z3_ast Z3_API Z3_mk_zero_ext(Z3_context c, unsigned i, Z3_ast t1)
Extend the given bit-vector with zeros to the (unsigned) equivalent bit-vector of size m+i,...
z3py.ZeroExt
def ZeroExt(n, a)
Definition: z3py.py:4393

Variable Documentation

◆ sat

sat = CheckSatResult(Z3_L_TRUE)

Definition at line 6892 of file z3py.py.

◆ unknown

unknown = CheckSatResult(Z3_L_UNDEF)

Definition at line 6894 of file z3py.py.

◆ unsat

unsat = CheckSatResult(Z3_L_FALSE)

Definition at line 6893 of file z3py.py.

◆ Z3_DEBUG

Z3_DEBUG = __debug__

Definition at line 59 of file z3py.py.

Generated on Sat Jan 14 2023 14:44:10 for Z3 by doxygen 1.9.1