(theory FloatingPoint
:smt-lib-version 2.6
:smt-lib-release "2017-11-24"
:written-by "Cesare Tinelli and Martin Brain"
:date "2014-05-27"
:last-updated "2015-04-25"
:update-history
"Note: history only accounts for content changes, not release changes.
2015-04-25 Updated to Version 2.5.
Updated reference to tech report.
"
:notes
"This is a theory of floating point numbers largely based on the IEEE standard
754-2008 for floating-point arithmetic (http://grouper.ieee.org/groups/754/)
but restricted to the binary case only.
A major extension over 754-2008 is that the theory has a sort for every
possible exponent and significand length.
Version 1 of the theory was based on proposal by P. Ruemmer and T. Wahl [RW10].
[RW10] Philipp Ruemmer and Thomas Wahl.
An SMT-LIB Theory of Binary Floating-Point Arithmetic.
Proceedings of the 8th International Workshop on
Satisfiability Modulo Theories (SMT'10), Edinburgh, UK, July 2010.
(http://www.philipp.ruemmer.org/publications/smt-fpa.pdf)
Version 2 was written by C. Tinelli using community feedback.
Version 3, the current one, was written by C. Tinelli and M. Brain following
further discussion within the SMT-LIB community, and then relaborated with
P. Ruemmer and T. Wahl.
A more detailed description of this version together with the rationale of
several models decisions as well as a formal semantics of the theory can be
found in
[BTRW15] Martin Brain, Cesare Tinelli, Philipp Ruemmer, and Thomas Wahl.
An Automatable Formal Semantics for IEEE-754 Floating-Point Arithmetic
Technical Report, 2015.
(http://smt-lib.org/papers/BTRW15.pdf)
The following additional people provided substantial feedback and directions:
François Bobot, David Cok, Alberto Griggio, Florian Lapschies, Leonardo de
Moura, Gabriele Paganelli, Cody Roux, Christoph Wintersteiger.
"
;-------
; Sorts
;-------
:sorts ((RoundingMode 0) (Real 0))
; Bit vector sorts, indexed by vector size
:sorts_description "All sort symbols of the form
(_ BitVec m)
where m is a numeral greater than 0."
; Floating point sort, indexed by the length of the exponent and significand
; components of the number
:sorts_description "All nullary sort symbols of the form
(_ FloatingPoint eb sb),
where eb and sb are numerals greater than 1."
:notes
"eb defines the number of bits in the exponent;
sb defines the number of bits in the significand, *including* the hidden bit.
"
; Short name for common floating point sorts
:sort ((Float16 0) (Float32 0) (Float64 0) (Float128 0))
:notes "
- Float16 is a synonym for (_ FloatingPoint 5 11)
- Float32 is a synonym for (_ FloatingPoint 8 24)
- Float64 is a synonym for (_ FloatingPoint 11 53)
- Float128 is a synonym for (_ FloatingPoint 15 113)
These correspond to the IEEE binary16, binary32, binary64 and binary128 formats.
"
;----------------
; Rounding modes
;----------------
; Constants for rounding modes, and their abbreviated version
:funs ((roundNearestTiesToEven RoundingMode) (RNE RoundingMode)
(roundNearestTiesToAway RoundingMode) (RNA RoundingMode)
(roundTowardPositive RoundingMode) (RTP RoundingMode)
(roundTowardNegative RoundingMode) (RTN RoundingMode)
(roundTowardZero RoundingMode) (RTZ RoundingMode)
)
;--------------------
; Value constructors
;--------------------
; Bitvector literals
:funs_description "
All binaries #bX of sort (_ BitVec m) where m is the number of digits in X.
All hexadecimals #xX of sort (_ BitVec m) where m is 4 times the number of
digits in X.
"
; FP literals as bit string triples, with the leading bit for the significand
; not represented (hidden bit)
:funs_description "All function symbols with declaration of the form
(fp (_ BitVec 1) (_ BitVec eb) (_ BitVec i) (_ FloatingPoint eb sb))
where eb and sb are numerals greater than 1 and i = sb - 1."
; Plus and minus infinity
:funs_description "All function symbols with declaration of the form
((_ +oo eb sb) (_ FloatingPoint eb sb))
((_ -oo eb sb) (_ FloatingPoint eb sb))
where eb and sb are numerals greater than 1."
:notes
"Semantically, for each eb and sb, there is exactly one +infinity value and
exactly one -infinity value in the set denoted by (_ FloatingPoint eb sb),
in agreement with the IEEE 754-2008 standard.
However, +/-infinity can have two representations in this theory.
E.g., +infinity for sort (_ FloatingPoint 2 3) is represented equivalently
by (_ +oo 2 3) and (fp #b0 #b11 #b00).
"
; Plus and minus zero
:funs_description "All function symbols with declaration of the form
((_ +zero eb sb) (_ FloatingPoint eb sb))
((_ -zero eb sb) (_ FloatingPoint eb sb))
where eb and sb are numerals greater than 1."
:note
"The +zero and -zero symbols are abbreviations for the corresponding fp literals.
E.g., (_ +zero 2 4) abbreviates (fp #b0 #b00 #b000)
(_ -zero 3 2) abbreviates (fp #b1 #b000 #b0)
"
; Non-numbers
:funs_description "All function symbols with declaration of the form
((_ NaN eb sb) (_ FloatingPoint eb sb))
where eb and sb are numerals greater than 1."
:notes
"For each eb and sb, there is exactly one NaN in the set denoted by
(_ FloatingPoint eb sb), in agreeement with Level 2 of IEEE 754-2008
(floating-point data). There is no distinction in this theory between
a ``quiet'' and a ``signaling'' NaN.
NaN has several representations, e.g.,(_ NaN eb sb) and any term of
the form (fp t #b1..1 s) where s is a binary containing at least a 1
and t is either #b0 or #b1.
"
;-----------
; Operators
;-----------
:funs_description "All function symbols with declarations of the form below
where eb and sb are numerals greater than 1.
; absolute value
(fp.abs (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
; negation (no rounding needed)
(fp.neg (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
; addition
(fp.add RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb)
(_ FloatingPoint eb sb))
; subtraction
(fp.sub RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb)
(_ FloatingPoint eb sb))
; multiplication
(fp.mul RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb)
(_ FloatingPoint eb sb))
; division
(fp.div RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb)
(_ FloatingPoint eb sb))
; fused multiplication and addition; (x * y) + z
(fp.fma RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) (_ FloatingPoint eb sb)
(_ FloatingPoint eb sb))
; square root
(fp.sqrt RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
; remainder: x - y * n, where n in Z is nearest to x/y
(fp.rem (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
; rounding to integral
(fp.roundToIntegral RoundingMode (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
; minimum and maximum
(fp.min (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
(fp.max (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) (_ FloatingPoint eb sb))
; comparison operators
; Note that all comparisons evaluate to false if either argument is NaN
(fp.leq (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) Bool :chainable)
(fp.lt (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) Bool :chainable)
(fp.geq (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) Bool :chainable)
(fp.gt (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) Bool :chainable)
; IEEE 754-2008 equality (as opposed to SMT-LIB =)
(fp.eq (_ FloatingPoint eb sb) (_ FloatingPoint eb sb) Bool :chainable)
; Classification of numbers
(fp.isNormal (_ FloatingPoint eb sb) Bool)
(fp.isSubnormal (_ FloatingPoint eb sb) Bool)
(fp.isZero (_ FloatingPoint eb sb) Bool)
(fp.isInfinite (_ FloatingPoint eb sb) Bool)
(fp.isNaN (_ FloatingPoint eb sb) Bool)
(fp.isNegative (_ FloatingPoint eb sb) Bool)
(fp.isPositive (_ FloatingPoint eb sb) Bool)
"
:note
"(fp.eq x y) evaluates to true if x evaluates to -zero and y to +zero, or vice versa.
fp.eq and all the other comparison operators evaluate to false if one of their
arguments is NaN.
"
;------------------------------
; Conversions from other sorts
;------------------------------
:funs_description "All function symbols with declarations of the form below
where m is a numerals greater than 0 and eb, sb, mb and nb are numerals
greater than 1.
; from single bitstring representation in IEEE 754-2008 interchange format,
; with m = eb + sb
((_ to_fp eb sb) (_ BitVec m) (_ FloatingPoint eb sb))
; from another floating point sort
((_ to_fp eb sb) RoundingMode (_ FloatingPoint mb nb) (_ FloatingPoint eb sb))
; from real
((_ to_fp eb sb) RoundingMode Real (_ FloatingPoint eb sb))
; from signed machine integer, represented as a 2's complement bit vector
((_ to_fp eb sb) RoundingMode (_ BitVec m) (_ FloatingPoint eb sb))
; from unsigned machine integer, represented as bit vector
((_ to_fp_unsigned eb sb) RoundingMode (_ BitVec m) (_ FloatingPoint eb sb))
"
;----------------------------
; Conversions to other sorts
;----------------------------
:funs_description "All function symbols with declarations of the form below
where m is a numeral greater than 0 and eb and sb are numerals greater than 1.
; to unsigned machine integer, represented as a bit vector
((_ fp.to_ubv m) RoundingMode (_ FloatingPoint eb sb) (_ BitVec m))
; to signed machine integer, represented as a 2's complement bit vector
((_ fp.to_sbv m) RoundingMode (_ FloatingPoint eb sb) (_ BitVec m))
; to real
(fp.to_real (_ FloatingPoint eb sb) Real)
"
:notes
"All fp.to_* functions are unspecified for NaN and infinity input values.
In addition, fp.to_ubv and fp.to_sbv are unspecified for finite number inputs
that are out of range (which includes all negative numbers for fp.to_ubv).
This means for instance that the formula
(= (fp.to_real (_ NaN 8 24)) (fp.to_real (fp c1 c2 c3)))
is satisfiable in this theory for all binary constants c1, c2, and c3
(of the proper sort).
"
:note
"There is no function for converting from (_ FloatingPoint eb sb) to the
corresponding IEEE 754-2008 binary format, as a bit vector (_ BitVec m) with
m = eb + sb, because (_ NaN eb sb) has multiple, well-defined representations.
Instead, an encoding of the kind below is recommended, where f is a term
of sort (_ FloatingPoint eb sb):
(declare-fun b () (_ BitVec m))
(assert (= ((_ to_fp eb sb) b) f))
"
;--------
; Values
;--------
:values "For all m,n > 1, the values of sort (_ FloatingPoint m n) are
- (_ +oo m n)
- (_ -oo m n)
- (_ NaN m n)
- all terms of the form (fp c1 c2 c3) where
- c1 is the binary #b0 or #b1
- c2 is a binary of size m other than #b1...1 (all 1s)
- c3 is a binary of size n-1
The set of values for RoundingMode is {RNE, RNA, RTP, RTN, RTZ}.
"
:notes
"No values are specified for the sorts Real and (_ BitVec n) in this theory.
They are specified in the theory declarations Reals and FixedSizeBitVectors,
respectively.
"
;-----------
; Semantics
;-----------
:note
"The semantics of this theory is described somewhat informally here.
A rigorous, self-contained specification can be found in [BTRW14]:
'An Automatable Formal Semantics for IEEE-754 Floating-Point Arithmetic'
and it takes precedence in the case of any (unintended) inconsistencies.
"
:definition
"For every expanded signature Sigma, the instance of FloatingPoints with
that signature is the theory consisting of all Sigma-models that satisfy
the constraints detailed below.
We use [[ _ ]] to denote the meaning of a sort or function symbol in
a given Sigma-model.
o (_ FloatingPoint eb sb)
[[(_ FloatingPoint eb sb)]] is the set of all the binary floating point
numbers with eb bits for the exponent and sb bits for the significand,
as defined by IEEE 754-2008.
Technically, [[(_ FloatingPoint eb sb)]] is the union of the set
{not_a_number} with four sets N, S, Z, I of bit-vector triples
(corresponding to normal numbers, subnormal numbers, zeros and
infinities) of the form (s, e, m) where s, e, and m correspond
respectively to the sign, the exponent and the significand (see
the paper for more details).
Note that the (semantic) value not_a_number is shared across all
[[(_ FloatingPoint eb sb)]].
o (_ BitVec m), binary and hexadecimal constants
These are interpreted as in the theory FixedSizeBitVectors.
o Real
[[Real]] is the set of real numbers.
o RoundingMode
[[RoundingMode]] is the set of the 5 rounding modes defined by IEEE 754-2008.
o (roundNearestTiesToEven RoundingMode), (roundNearestTiesToAway RoundingMode), ...
[[roundNearestTiesToEven]], [[roundNearestTiesToAway]], [[roundTowardPositive]],
[[roundTowardNegative]], and [[roundTowardZero]] are the 5 distinct elements
of [[RoundingMode]], and each corresponds to the rounding mode suggested by
the symbol's name.
o (RNE RoundingMode), (RNA RoundingMode), ...
[[RNE]] = [[roundNearestTiesToEven]];
[[RNA]] = [[roundNearestTiesToAway]];
[[RTP]] = [[roundTowardPositive]];
[[RTN]] = [[roundTowardNegative]];
[[RTZ]] = [[roundTowardZero]].
o (fp (_ BitVec 1) (_ BitVec eb) (_ BitVec i) (_ FloatingPoint eb sb))
[[fp]] returns the element of [[(_ FloatingPoint eb sb)]] whose IEEE 754-2008
binary encoding matches the input bit strings:
for all bitvectors
b1 in [[(_ BitVec 1)]], b2 in [[(_ BitVec eb)]] and b3 in [[(_ BitVec i)]],
[[fp]](b1, b2 ,b3) is the binary floating point number encoded in the IEEE
754-2008 standard with sign bit b1, exponent bits b2, and significant bit b3
(with 1 hidden bit).
Note that not_a_number can be denoted with fp terms as well. For instance, in
(_ FloatingPoint 2 2),
[[(_ NaN 2 2)]] = [[fp]]([[#b0]], [[#b11]], [[#b1]])
= [[fp]]([[#b1]], [[#b11]], [[#b1]])
Similarly,
[[(_ +oo 2 2)]] = [[fp]]([[#b0]], [[#b11]], [[#b0]])
[[(_ -oo 2 2)]] = [[fp]]([[#b1]], [[#b11]], [[#b0]])
o ((_ +oo eb sb) (_ FloatingPoint eb sb))
((_ -oo eb sb) (_ FloatingPoint eb sb))
((_ NaN eb sb) (_ FloatingPoint eb sb))
((_ +zero eb sb) (_ FloatingPoint eb sb))
((_ -zero eb sb) (_ FloatingPoint eb sb))
[[(_ +oo eb sb)]] is +infinity
[[(_ -oo eb sb)]] is -infinity
[[(_ NaN eb sb)]] is not_a_number
[[(_ +zero eb sb)]] is [[fp]]([[#b0]], [[#b0..0]], [[#b0..0]]) where
the first bitvector literal has eb 0s and
the second has sb - 1 0s
[[(_ -zero eb sb)]] is [[fp]]([[#b1]], [[#b0..0]], [[#b0..0]]) where
the first bitvector literal has eb 0s and
the second has sb - 1 0s
o ((_ to_fp eb sb) (_ BitVec m) (_ FloatingPoint eb sb))
[[(_ to_fp eb sb)]](b) = [[fp]](b[m-1:m-1], b[eb+sb-1:sb], b[sb-1:0])
where b[p:q] denotes the subvector of bitvector b between positions p and q.
o (fp.to_real (_ FloatingPoint eb sb) Real)
[[fp.to_real]](x) is the real number represented by x if x is not in
{-infinity, -infinity, not_a_number}. Otherwise, it is unspecified.
o ((_ to_fp eb sb) RoundingMode (_ FloatingPoint m n) (_ FloatingPoint eb sb))
[[(_ to_fp eb sb)]](r, x) = x if x in {+infinity, -infinity, not_a_number}.
[[(_ to_fp eb sb)]](r, x) = +/-infinity if [[fp.to_real]](x) is too large/too
small to be represented as a finite number of [[(_ FloatingPoint eb sb)]];
[[(_ to_fp eb sb)]](r, x) = y otherwise, where y is the finite number
such that [[fp.to_real]](y) is closest to [[fp.to_real]](x) according to
rounding mode r.
o ((_ to_fp eb sb) RoundingMode Real (_ FloatingPoint eb sb))
[[(_ to_fp eb sb)]](r, x) = +/-infinity if x is too large/too small
to be represented as a finite number of [[(_ FloatingPoint eb sb)]];
[[(_ to_fp eb sb)]](r, x) = y otherwise, where y is the finite number
such that [[fp.to_real]](y) is closest to x according to rounding mode r.
o ((_ to_fp eb sb) RoundingMode (_ BitVec m) (_ FloatingPoint eb sb))
Let b in [[(_ BitVec m)]] and let n be the signed integer represented by b
(in 2's complement format).
[[(_ to_fp eb sb)]](r, b) = +/-infinity if n is too large/too small to be
represented as a finite number of [[(_ FloatingPoint eb sb)]];
[[(_ to_fp eb sb)]](r, x) = y otherwise, where y is the finite number
such that [[fp.to_real]](y) is closest to n according to rounding mode r.
o ((_ to_fp_unsigned eb sb) RoundingMode (_ BitVec m) (_ FloatingPoint eb sb))
Let b in [[(_ BitVec m)]] and let n be the unsigned integer represented by b.
[[(_ to_fp_unsigned eb sb)]](r, x) = +infinity if n is too large to be
represented as a finite number of [[(_ FloatingPoint eb sb)]];
[[(_ to_fp_unsigned eb sb)]](r, x) = y otherwise, where y is the finite number
such that [[fp.to_real]](y) is closest to n according to rounding mode r.
o ((_ fp.to_ubv m) RoundingMode (_ FloatingPoint eb sb) (_ BitVec m))
[[(_ fp.to_ubv m)]](r, x) = b if the unsigned integer n represented by b is
the closest integer according to rounding mode r to the real number
represented by x, and n is in the range [0, 2^m - 1].
[[(_ fp.to_ubv m)]](r, x) is unspecified in all other cases (including when
x is in {-infinity, -infinity, not_a_number}).
o ((_ fp.to_sbv m) RoundingMode (_ FloatingPoint eb sb) (_ BitVec m))
[[(_ fp.to_sbv m)]](r, x) = b if the signed integer n represented by b
(in 2's complement format) is the closest integer according to rounding mode
r to the real number represented by x, and n is in the range
[-2^{m-1}, 2^{m-1} - 1].
[[(_ fp.to_sbv m)]](r, x) is unspecified in all other cases (including when
x is in {-infinity, -infinity, not_a_number}).
o (fp.isNormal (_ FloatingPoint eb sb) Bool)
[[fp.isNormal]](x) = true iff x is a normal number.
o (fp.isSubnormal (_ FloatingPoint eb sb) Bool)
[[fp.isSubnormal]](x) = true iff x is a subnormal number.
o (fp.isZero (_ FloatingPoint eb sb) Bool)
[[fp.isZero]](x) = true iff x is positive or negative zero.
o (fp.isInfinite (_ FloatingPoint eb sb) Bool)
[[fp.isInfinite]](x) = true iff x is +infinity or -infinity.
o (fp.isNaN (_ FloatingPoint eb sb) Bool)
[[fp.isNaN]](x) = true iff x = not_a_number.
o (fp.isNegative (_ FloatingPoint eb sb) Bool)
[[fp.isNegative]](x) = true iff x is [[-zero]] or [[fp.lt]](x, [[-zero]]) holds.
o (fp.isPositive (_ FloatingPoint eb sb) Bool)
[[fp.isPositive]](x) = true iff x is [[+zero]] or [[fp.lt]]([[+zero]], x) holds.
o all the other function symbols are interpreted as described in [BTRW15].
"
)