""" Limits ====== Implemented according to the PhD thesis http://www.cybertester.com/data/gruntz.pdf, which contains very thorough descriptions of the algorithm including many examples. We summarize here the gist of it. All functions are sorted according to how rapidly varying they are at infinity using the following rules. Any two functions f and g can be compared using the properties of L: L=lim log|f(x)| / log|g(x)| (for x -> oo) We define >, < ~ according to:: 1. f > g .... L=+-oo we say that: - f is greater than any power of g - f is more rapidly varying than g - f goes to infinity/zero faster than g 2. f < g .... L=0 we say that: - f is lower than any power of g 3. f ~ g .... L!=0, +-oo we say that: - both f and g are bounded from above and below by suitable integral powers of the other Examples ======== :: 2 < x < exp(x) < exp(x**2) < exp(exp(x)) 2 ~ 3 ~ -5 x ~ x**2 ~ x**3 ~ 1/x ~ x**m ~ -x exp(x) ~ exp(-x) ~ exp(2x) ~ exp(x)**2 ~ exp(x+exp(-x)) f ~ 1/f So we can divide all the functions into comparability classes (x and x^2 belong to one class, exp(x) and exp(-x) belong to some other class). In principle, we could compare any two functions, but in our algorithm, we do not compare anything below the class 2~3~-5 (for example log(x) is below this), so we set 2~3~-5 as the lowest comparability class. Given the function f, we find the list of most rapidly varying (mrv set) subexpressions of it. This list belongs to the same comparability class. Let's say it is {exp(x), exp(2x)}. Using the rule f ~ 1/f we find an element "w" (either from the list or a new one) from the same comparability class which goes to zero at infinity. In our example we set w=exp(-x) (but we could also set w=exp(-2x) or w=exp(-3x) ...). We rewrite the mrv set using w, in our case {1/w, 1/w^2}, and substitute it into f. Then we expand f into a series in w:: f = c0*w^e0 + c1*w^e1 + ... + O(w^en), where e0oo, lim f = lim c0*w^e0, because all the other terms go to zero, because w goes to zero faster than the ci and ei. So:: for e0>0, lim f = 0 for e0<0, lim f = +-oo (the sign depends on the sign of c0) for e0=0, lim f = lim c0 We need to recursively compute limits at several places of the algorithm, but as is shown in the PhD thesis, it always finishes. Important functions from the implementation: compare(a, b, x) compares "a" and "b" by computing the limit L. mrv(e, x) returns list of most rapidly varying (mrv) subexpressions of "e" rewrite(e, Omega, x, wsym) rewrites "e" in terms of w leadterm(f, x) returns the lowest power term in the series of f mrv_leadterm(e, x) returns the lead term (c0, e0) for e limitinf(e, x) computes lim e (for x->oo) limit(e, z, z0) computes any limit by converting it to the case x->oo All the functions are really simple and straightforward except rewrite(), which is the most difficult/complex part of the algorithm. When the algorithm fails, the bugs are usually in the series expansion (i.e. in SymPy) or in rewrite. This code is almost exact rewrite of the Maple code inside the Gruntz thesis. Debugging --------- Because the gruntz algorithm is highly recursive, it's difficult to figure out what went wrong inside a debugger. Instead, turn on nice debug prints by defining the environment variable SYMPY_DEBUG. For example: [user@localhost]: SYMPY_DEBUG=True ./bin/isympy In [1]: limit(sin(x)/x, x, 0) limitinf(_x*sin(1/_x), _x) = 1 +-mrv_leadterm(_x*sin(1/_x), _x) = (1, 0) | +-mrv(_x*sin(1/_x), _x) = set([_x]) | | +-mrv(_x, _x) = set([_x]) | | +-mrv(sin(1/_x), _x) = set([_x]) | | +-mrv(1/_x, _x) = set([_x]) | | +-mrv(_x, _x) = set([_x]) | +-mrv_leadterm(exp(_x)*sin(exp(-_x)), _x, set([exp(_x)])) = (1, 0) | +-rewrite(exp(_x)*sin(exp(-_x)), set([exp(_x)]), _x, _w) = (1/_w*sin(_w), -_x) | +-sign(_x, _x) = 1 | +-mrv_leadterm(1, _x) = (1, 0) +-sign(0, _x) = 0 +-limitinf(1, _x) = 1 And check manually which line is wrong. Then go to the source code and debug this function to figure out the exact problem. """ from functools import reduce from sympy.core import Basic, S, Mul, PoleError from sympy.core.cache import cacheit from sympy.core.numbers import ilcm, I, oo from sympy.core.symbol import Dummy, Wild from sympy.core.traversal import bottom_up from sympy.functions import log, exp, sign as _sign from sympy.series.order import Order from sympy.simplify import logcombine from sympy.simplify.powsimp import powsimp, powdenest from sympy.utilities.misc import debug_decorator as debug from sympy.utilities.timeutils import timethis timeit = timethis('gruntz') def compare(a, b, x): """Returns "<" if a" for a>b""" # log(exp(...)) must always be simplified here for termination la, lb = log(a), log(b) if isinstance(a, Basic) and (isinstance(a, exp) or (a.is_Pow and a.base == S.Exp1)): la = a.exp if isinstance(b, Basic) and (isinstance(b, exp) or (b.is_Pow and b.base == S.Exp1)): lb = b.exp c = limitinf(la/lb, x) if c == 0: return "<" elif c.is_infinite: return ">" else: return "=" class SubsSet(dict): """ Stores (expr, dummy) pairs, and how to rewrite expr-s. Explanation =========== The gruntz algorithm needs to rewrite certain expressions in term of a new variable w. We cannot use subs, because it is just too smart for us. For example:: > Omega=[exp(exp(_p - exp(-_p))/(1 - 1/_p)), exp(exp(_p))] > O2=[exp(-exp(_p) + exp(-exp(-_p))*exp(_p)/(1 - 1/_p))/_w, 1/_w] > e = exp(exp(_p - exp(-_p))/(1 - 1/_p)) - exp(exp(_p)) > e.subs(Omega[0],O2[0]).subs(Omega[1],O2[1]) -1/w + exp(exp(p)*exp(-exp(-p))/(1 - 1/p)) is really not what we want! So we do it the hard way and keep track of all the things we potentially want to substitute by dummy variables. Consider the expression:: exp(x - exp(-x)) + exp(x) + x. The mrv set is {exp(x), exp(-x), exp(x - exp(-x))}. We introduce corresponding dummy variables d1, d2, d3 and rewrite:: d3 + d1 + x. This class first of all keeps track of the mapping expr->variable, i.e. will at this stage be a dictionary:: {exp(x): d1, exp(-x): d2, exp(x - exp(-x)): d3}. [It turns out to be more convenient this way round.] But sometimes expressions in the mrv set have other expressions from the mrv set as subexpressions, and we need to keep track of that as well. In this case, d3 is really exp(x - d2), so rewrites at this stage is:: {d3: exp(x-d2)}. The function rewrite uses all this information to correctly rewrite our expression in terms of w. In this case w can be chosen to be exp(-x), i.e. d2. The correct rewriting then is:: exp(-w)/w + 1/w + x. """ def __init__(self): self.rewrites = {} def __repr__(self): return super().__repr__() + ', ' + self.rewrites.__repr__() def __getitem__(self, key): if key not in self: self[key] = Dummy() return dict.__getitem__(self, key) def do_subs(self, e): """Substitute the variables with expressions""" for expr, var in self.items(): e = e.xreplace({var: expr}) return e def meets(self, s2): """Tell whether or not self and s2 have non-empty intersection""" return set(self.keys()).intersection(list(s2.keys())) != set() def union(self, s2, exps=None): """Compute the union of self and s2, adjusting exps""" res = self.copy() tr = {} for expr, var in s2.items(): if expr in self: if exps: exps = exps.xreplace({var: res[expr]}) tr[var] = res[expr] else: res[expr] = var for var, rewr in s2.rewrites.items(): res.rewrites[var] = rewr.xreplace(tr) return res, exps def copy(self): """Create a shallow copy of SubsSet""" r = SubsSet() r.rewrites = self.rewrites.copy() for expr, var in self.items(): r[expr] = var return r @debug def mrv(e, x): """Returns a SubsSet of most rapidly varying (mrv) subexpressions of 'e', and e rewritten in terms of these""" e = powsimp(e, deep=True, combine='exp') if not isinstance(e, Basic): raise TypeError("e should be an instance of Basic") if not e.has(x): return SubsSet(), e elif e == x: s = SubsSet() return s, s[x] elif e.is_Mul or e.is_Add: i, d = e.as_independent(x) # throw away x-independent terms if d.func != e.func: s, expr = mrv(d, x) return s, e.func(i, expr) a, b = d.as_two_terms() s1, e1 = mrv(a, x) s2, e2 = mrv(b, x) return mrv_max1(s1, s2, e.func(i, e1, e2), x) elif e.is_Pow and e.base != S.Exp1: e1 = S.One while e.is_Pow: b1 = e.base e1 *= e.exp e = b1 if b1 == 1: return SubsSet(), b1 if e1.has(x): base_lim = limitinf(b1, x) if base_lim is S.One: return mrv(exp(e1 * (b1 - 1)), x) return mrv(exp(e1 * log(b1)), x) else: s, expr = mrv(b1, x) return s, expr**e1 elif isinstance(e, log): s, expr = mrv(e.args[0], x) return s, log(expr) elif isinstance(e, exp) or (e.is_Pow and e.base == S.Exp1): # We know from the theory of this algorithm that exp(log(...)) may always # be simplified here, and doing so is vital for termination. if isinstance(e.exp, log): return mrv(e.exp.args[0], x) # if a product has an infinite factor the result will be # infinite if there is no zero, otherwise NaN; here, we # consider the result infinite if any factor is infinite li = limitinf(e.exp, x) if any(_.is_infinite for _ in Mul.make_args(li)): s1 = SubsSet() e1 = s1[e] s2, e2 = mrv(e.exp, x) su = s1.union(s2)[0] su.rewrites[e1] = exp(e2) return mrv_max3(s1, e1, s2, exp(e2), su, e1, x) else: s, expr = mrv(e.exp, x) return s, exp(expr) elif e.is_Function: l = [mrv(a, x) for a in e.args] l2 = [s for (s, _) in l if s != SubsSet()] if len(l2) != 1: # e.g. something like BesselJ(x, x) raise NotImplementedError("MRV set computation for functions in" " several variables not implemented.") s, ss = l2[0], SubsSet() args = [ss.do_subs(x[1]) for x in l] return s, e.func(*args) elif e.is_Derivative: raise NotImplementedError("MRV set computation for derviatives" " not implemented yet.") raise NotImplementedError( "Don't know how to calculate the mrv of '%s'" % e) def mrv_max3(f, expsf, g, expsg, union, expsboth, x): """ Computes the maximum of two sets of expressions f and g, which are in the same comparability class, i.e. max() compares (two elements of) f and g and returns either (f, expsf) [if f is larger], (g, expsg) [if g is larger] or (union, expsboth) [if f, g are of the same class]. """ if not isinstance(f, SubsSet): raise TypeError("f should be an instance of SubsSet") if not isinstance(g, SubsSet): raise TypeError("g should be an instance of SubsSet") if f == SubsSet(): return g, expsg elif g == SubsSet(): return f, expsf elif f.meets(g): return union, expsboth c = compare(list(f.keys())[0], list(g.keys())[0], x) if c == ">": return f, expsf elif c == "<": return g, expsg else: if c != "=": raise ValueError("c should be =") return union, expsboth def mrv_max1(f, g, exps, x): """Computes the maximum of two sets of expressions f and g, which are in the same comparability class, i.e. mrv_max1() compares (two elements of) f and g and returns the set, which is in the higher comparability class of the union of both, if they have the same order of variation. Also returns exps, with the appropriate substitutions made. """ u, b = f.union(g, exps) return mrv_max3(f, g.do_subs(exps), g, f.do_subs(exps), u, b, x) @debug @cacheit @timeit def sign(e, x): """ Returns a sign of an expression e(x) for x->oo. :: e > 0 for x sufficiently large ... 1 e == 0 for x sufficiently large ... 0 e < 0 for x sufficiently large ... -1 The result of this function is currently undefined if e changes sign arbitrarily often for arbitrarily large x (e.g. sin(x)). Note that this returns zero only if e is *constantly* zero for x sufficiently large. [If e is constant, of course, this is just the same thing as the sign of e.] """ if not isinstance(e, Basic): raise TypeError("e should be an instance of Basic") if e.is_positive: return 1 elif e.is_negative: return -1 elif e.is_zero: return 0 elif not e.has(x): e = logcombine(e) return _sign(e) elif e == x: return 1 elif e.is_Mul: a, b = e.as_two_terms() sa = sign(a, x) if not sa: return 0 return sa * sign(b, x) elif isinstance(e, exp): return 1 elif e.is_Pow: if e.base == S.Exp1: return 1 s = sign(e.base, x) if s == 1: return 1 if e.exp.is_Integer: return s**e.exp elif isinstance(e, log): return sign(e.args[0] - 1, x) # if all else fails, do it the hard way c0, e0 = mrv_leadterm(e, x) return sign(c0, x) @debug @timeit @cacheit def limitinf(e, x, leadsimp=False): """Limit e(x) for x-> oo. Explanation =========== If ``leadsimp`` is True, an attempt is made to simplify the leading term of the series expansion of ``e``. That may succeed even if ``e`` cannot be simplified. """ # rewrite e in terms of tractable functions only if not e.has(x): return e # e is a constant if e.has(Order): e = e.expand().removeO() if not x.is_positive or x.is_integer: # We make sure that x.is_positive is True and x.is_integer is None # so we get all the correct mathematical behavior from the expression. # We need a fresh variable. p = Dummy('p', positive=True) e = e.subs(x, p) x = p e = e.rewrite('tractable', deep=True, limitvar=x) e = powdenest(e) c0, e0 = mrv_leadterm(e, x) sig = sign(e0, x) if sig == 1: return S.Zero # e0>0: lim f = 0 elif sig == -1: # e0<0: lim f = +-oo (the sign depends on the sign of c0) if c0.match(I*Wild("a", exclude=[I])): return c0*oo s = sign(c0, x) # the leading term shouldn't be 0: if s == 0: raise ValueError("Leading term should not be 0") return s*oo elif sig == 0: if leadsimp: c0 = c0.simplify() return limitinf(c0, x, leadsimp) # e0=0: lim f = lim c0 else: raise ValueError("{} could not be evaluated".format(sig)) def moveup2(s, x): r = SubsSet() for expr, var in s.items(): r[expr.xreplace({x: exp(x)})] = var for var, expr in s.rewrites.items(): r.rewrites[var] = s.rewrites[var].xreplace({x: exp(x)}) return r def moveup(l, x): return [e.xreplace({x: exp(x)}) for e in l] @debug @timeit def calculate_series(e, x, logx=None): """ Calculates at least one term of the series of ``e`` in ``x``. This is a place that fails most often, so it is in its own function. """ for t in e.lseries(x, logx=logx): # bottom_up function is required for a specific case - when e is # -exp(p/(p + 1)) + exp(-p**2/(p + 1) + p) t = bottom_up(t, lambda w: getattr(w, 'normal', lambda: w)()) # And the expression # `(-sin(1/x) + sin((x + exp(x))*exp(-x)/x))*exp(x)` # from the first test of test_gruntz_eval_special needs to # be expanded. But other forms need to be have at least # factor_terms applied. `factor` accomplishes both and is # faster than using `factor_terms` for the gruntz suite. It # does not appear that use of `cancel` is necessary. # t = cancel(t, expand=False) t = t.factor() if t.has(exp) and t.has(log): t = powdenest(t) if not t.is_zero: break return t @debug @timeit @cacheit def mrv_leadterm(e, x): """Returns (c0, e0) for e.""" Omega = SubsSet() if not e.has(x): return (e, S.Zero) if Omega == SubsSet(): Omega, exps = mrv(e, x) if not Omega: # e really does not depend on x after simplification return exps, S.Zero if x in Omega: # move the whole omega up (exponentiate each term): Omega_up = moveup2(Omega, x) exps_up = moveup([exps], x)[0] # NOTE: there is no need to move this down! Omega = Omega_up exps = exps_up # # The positive dummy, w, is used here so log(w*2) etc. will expand; # a unique dummy is needed in this algorithm # # For limits of complex functions, the algorithm would have to be # improved, or just find limits of Re and Im components separately. # w = Dummy("w", positive=True) f, logw = rewrite(exps, Omega, x, w) series = calculate_series(f, w, logx=logw) try: lt = series.leadterm(w, logx=logw) except (ValueError, PoleError): lt = f.as_coeff_exponent(w) # as_coeff_exponent won't always split in required form. It may simply # return (f, 0) when a better form may be obtained. Example (-x)**(-pi) # can be written as (-1**(-pi), -pi) which as_coeff_exponent does not return if lt[0].has(w): base = f.as_base_exp()[0].as_coeff_exponent(w) ex = f.as_base_exp()[1] lt = (base[0]**ex, base[1]*ex) return (lt[0].subs(log(w), logw), lt[1]) def build_expression_tree(Omega, rewrites): r""" Helper function for rewrite. We need to sort Omega (mrv set) so that we replace an expression before we replace any expression in terms of which it has to be rewritten:: e1 ---> e2 ---> e3 \ -> e4 Here we can do e1, e2, e3, e4 or e1, e2, e4, e3. To do this we assemble the nodes into a tree, and sort them by height. This function builds the tree, rewrites then sorts the nodes. """ class Node: def __init__(self): self.before = [] self.expr = None self.var = None def ht(self): return reduce(lambda x, y: x + y, [x.ht() for x in self.before], 1) nodes = {} for expr, v in Omega: n = Node() n.var = v n.expr = expr nodes[v] = n for _, v in Omega: if v in rewrites: n = nodes[v] r = rewrites[v] for _, v2 in Omega: if r.has(v2): n.before.append(nodes[v2]) return nodes @debug @timeit def rewrite(e, Omega, x, wsym): """e(x) ... the function Omega ... the mrv set wsym ... the symbol which is going to be used for w Returns the rewritten e in terms of w and log(w). See test_rewrite1() for examples and correct results. """ if not isinstance(Omega, SubsSet): raise TypeError("Omega should be an instance of SubsSet") if len(Omega) == 0: raise ValueError("Length cannot be 0") # all items in Omega must be exponentials for t in Omega.keys(): if not isinstance(t, exp): raise ValueError("Value should be exp") rewrites = Omega.rewrites Omega = list(Omega.items()) nodes = build_expression_tree(Omega, rewrites) Omega.sort(key=lambda x: nodes[x[1]].ht(), reverse=True) # make sure we know the sign of each exp() term; after the loop, # g is going to be the "w" - the simplest one in the mrv set for g, _ in Omega: sig = sign(g.exp, x) if sig != 1 and sig != -1: raise NotImplementedError('Result depends on the sign of %s' % sig) if sig == 1: wsym = 1/wsym # if g goes to oo, substitute 1/w # O2 is a list, which results by rewriting each item in Omega using "w" O2 = [] denominators = [] for f, var in Omega: c = limitinf(f.exp/g.exp, x) if c.is_Rational: denominators.append(c.q) arg = f.exp if var in rewrites: if not isinstance(rewrites[var], exp): raise ValueError("Value should be exp") arg = rewrites[var].args[0] O2.append((var, exp((arg - c*g.exp).expand())*wsym**c)) # Remember that Omega contains subexpressions of "e". So now we find # them in "e" and substitute them for our rewriting, stored in O2 # the following powsimp is necessary to automatically combine exponentials, # so that the .xreplace() below succeeds: # TODO this should not be necessary f = powsimp(e, deep=True, combine='exp') for a, b in O2: f = f.xreplace({a: b}) for _, var in Omega: assert not f.has(var) # finally compute the logarithm of w (logw). logw = g.exp if sig == 1: logw = -logw # log(w)->log(1/w)=-log(w) # Some parts of SymPy have difficulty computing series expansions with # non-integral exponents. The following heuristic improves the situation: exponent = reduce(ilcm, denominators, 1) f = f.subs({wsym: wsym**exponent}) logw /= exponent return f, logw def gruntz(e, z, z0, dir="+"): """ Compute the limit of e(z) at the point z0 using the Gruntz algorithm. Explanation =========== ``z0`` can be any expression, including oo and -oo. For ``dir="+"`` (default) it calculates the limit from the right (z->z0+) and for ``dir="-"`` the limit from the left (z->z0-). For infinite z0 (oo or -oo), the dir argument doesn't matter. This algorithm is fully described in the module docstring in the gruntz.py file. It relies heavily on the series expansion. Most frequently, gruntz() is only used if the faster limit() function (which uses heuristics) fails. """ if not z.is_symbol: raise NotImplementedError("Second argument must be a Symbol") # convert all limits to the limit z->oo; sign of z is handled in limitinf r = None if z0 == oo: e0 = e elif z0 == -oo: e0 = e.subs(z, -z) else: if str(dir) == "-": e0 = e.subs(z, z0 - 1/z) elif str(dir) == "+": e0 = e.subs(z, z0 + 1/z) else: raise NotImplementedError("dir must be '+' or '-'") try: r = limitinf(e0, z) except ValueError: r = limitinf(e0, z, leadsimp=True) # This is a bit of a heuristic for nice results... we always rewrite # tractable functions in terms of familiar intractable ones. # It might be nicer to rewrite the exactly to what they were initially, # but that would take some work to implement. return r.rewrite('intractable', deep=True)