# -*- coding: utf-8 -*- """ pint.formatter ~~~~~~~~~~~~~~ Format units for pint. :copyright: 2016 by Pint Authors, see AUTHORS for more details. :license: BSD, see LICENSE for more details. """ from __future__ import division, unicode_literals, print_function, absolute_import import re from .babel_names import _babel_units, _babel_lengths from pint.compat import babel_units, Loc __JOIN_REG_EXP = re.compile("\{\d*\}") def _join(fmt, iterable): """Join an iterable with the format specified in fmt. The format can be specified in two ways: - PEP3101 format with two replacement fields (eg. '{0} * {1}') - The concatenating string (eg. ' * ') """ if not iterable: return '' if not __JOIN_REG_EXP.search(fmt): return fmt.join(iterable) miter = iter(iterable) first = next(miter) for val in miter: ret = fmt.format(first, val) first = ret return first _PRETTY_EXPONENTS = '⁰¹²³⁴⁵⁶⁷⁸⁹' def _pretty_fmt_exponent(num): """Format an number into a pretty printed exponent. """ # TODO: Will not work for decimals ret = '{0:n}'.format(num).replace('-', '⁻') for n in range(10): ret = ret.replace(str(n), _PRETTY_EXPONENTS[n]) return ret #: _FORMATS maps format specifications to the corresponding argument set to #: formatter(). _FORMATS = { 'P': { # Pretty format. 'as_ratio': True, 'single_denominator': False, 'product_fmt': '·', 'division_fmt': '/', 'power_fmt': '{0}{1}', 'parentheses_fmt': '({0})', 'exp_call': _pretty_fmt_exponent, }, 'L': { # Latex format. 'as_ratio': True, 'single_denominator': True, 'product_fmt': r' \cdot ', 'division_fmt': r'\frac[{0}][{1}]', 'power_fmt': '{0}^[{1}]', 'parentheses_fmt': r'\left({0}\right)', }, 'H': { # HTML format. 'as_ratio': True, 'single_denominator': True, 'product_fmt': r' ', 'division_fmt': r'{0}/{1}', 'power_fmt': '{0}{1}', 'parentheses_fmt': r'({0})', }, '': { # Default format. 'as_ratio': True, 'single_denominator': False, 'product_fmt': ' * ', 'division_fmt': ' / ', 'power_fmt': '{0} ** {1}', 'parentheses_fmt': r'({0})', }, 'C': { # Compact format. 'as_ratio': True, 'single_denominator': False, 'product_fmt': '*', # TODO: Should this just be ''? 'division_fmt': '/', 'power_fmt': '{0}**{1}', 'parentheses_fmt': r'({0})', }, } def formatter(items, as_ratio=True, single_denominator=False, product_fmt=' * ', division_fmt=' / ', power_fmt='{0} ** {1}', parentheses_fmt='({0})', exp_call=lambda x: '{0:n}'.format(x), locale=None, babel_length='long', babel_plural_form='one'): """Format a list of (name, exponent) pairs. :param items: a list of (name, exponent) pairs. :param as_ratio: True to display as ratio, False as negative powers. :param single_denominator: all with terms with negative exponents are collected together. :param product_fmt: the format used for multiplication. :param division_fmt: the format used for division. :param power_fmt: the format used for exponentiation. :param parentheses_fmt: the format used for parenthesis. :param locale: the locale object as defined in babel. :param babel_length: the length of the translated unit, as defined in babel cldr. :param babel_plural_form: the plural form, calculated as defined in babel. :return: the formula as a string. """ if not items: return '' if as_ratio: fun = lambda x: exp_call(abs(x)) else: fun = exp_call pos_terms, neg_terms = [], [] for key, value in sorted(items): if locale and babel_length and babel_plural_form and key in _babel_units: _key = _babel_units[key] locale = Loc.parse(locale) unit_patterns = locale._data['unit_patterns'] compound_unit_patterns = locale._data["compound_unit_patterns"] plural = 'one' if abs(value) <= 0 else babel_plural_form if babel_length not in _babel_lengths: other_lengths = [ _babel_length for _babel_length in reversed(_babel_lengths) \ if babel_length != _babel_length ] else: other_lengths = [] for _babel_length in [babel_length] + other_lengths: pat = unit_patterns.get(_key, {}).get(_babel_length, {}).get(plural) print(plural, _babel_length, pat) if pat is not None: key = pat.replace('{0}', '').strip() break division_fmt = compound_unit_patterns.get("per", {}).get(babel_length, division_fmt) power_fmt = '{0}{1}' exp_call = _pretty_fmt_exponent if value == 1: pos_terms.append(key) elif value > 0: pos_terms.append(power_fmt.format(key, fun(value))) elif value == -1 and as_ratio: neg_terms.append(key) else: neg_terms.append(power_fmt.format(key, fun(value))) if not as_ratio: # Show as Product: positive * negative terms ** -1 return _join(product_fmt, pos_terms + neg_terms) # Show as Ratio: positive terms / negative terms pos_ret = _join(product_fmt, pos_terms) or '1' if not neg_terms: return pos_ret if single_denominator: neg_ret = _join(product_fmt, neg_terms) if len(neg_terms) > 1: neg_ret = parentheses_fmt.format(neg_ret) else: neg_ret = _join(division_fmt, neg_terms) return _join(division_fmt, [pos_ret, neg_ret]) # Extract just the type from the specification mini-langage: see # http://docs.python.org/2/library/string.html#format-specification-mini-language # We also add uS for uncertainties. _BASIC_TYPES = frozenset('bcdeEfFgGnosxX%uS') _KNOWN_TYPES = frozenset(list(_FORMATS.keys()) + ['~']) def _parse_spec(spec): result = '' for ch in reversed(spec): if ch == '~' or ch in _BASIC_TYPES: continue elif ch in _KNOWN_TYPES: if result: raise ValueError("expected ':' after format specifier") else: result = ch elif ch.isalpha(): raise ValueError("Unknown conversion specified " + ch) else: break return result def format_unit(unit, spec, **kwspec): if not unit: return 'dimensionless' spec = _parse_spec(spec) fmt = dict(_FORMATS[spec]) fmt.update(kwspec) if spec == 'L': rm = [(r'\mathrm{{{0}}}'.format(u), p) for u, p in unit.items()] result = formatter(rm, **fmt) else: result = formatter(unit.items(), **fmt) if spec == 'L': result = result.replace('[', '{').replace(']', '}') return result def siunitx_format_unit(units): '''Returns LaTeX code for the unit that can be put into an siunitx command.''' # NOTE: unit registry is required to identify unit prefixes. registry = units._REGISTRY def _tothe(power): if isinstance(power, int) or (isinstance(power, float) and power.is_integer()): if power == 1: return '' elif power == 2: return r'\squared' elif power == 3: return r'\cubed' else: return r'\tothe{{{:d}}}'.format(int(power)) else: # limit float powers to 3 decimal places return r'\tothe{{{:.3f}}}'.format(power).rstrip('0') lpos = [] lneg = [] # loop through all units in the container for unit, power in sorted(units._units.items()): # remove unit prefix if it exists # siunitx supports \prefix commands l = lpos if power >= 0 else lneg prefix = None for p in registry._prefixes.values(): p = str(p) if len(p) > 0 and unit.find(p) == 0: prefix = p unit = unit.replace(prefix, '', 1) if power < 0: l.append(r'\per') if prefix is not None: l.append(r'\{0}'.format(prefix)) l.append(r'\{0}'.format(unit)) l.append(r'{0}'.format(_tothe(abs(power)))) return ''.join(lpos) + ''.join(lneg) def remove_custom_flags(spec): for flag in _KNOWN_TYPES: if flag: spec = spec.replace(flag, '') return spec def vector_to_latex(vec, fmtfun=lambda x: format(x, '.2f')): return matrix_to_latex([vec], fmtfun) def matrix_to_latex(matrix, fmtfun=lambda x: format('.2f', x)): ret = [] for row in matrix: ret += [' & '.join(fmtfun(f) for f in row)] return r'\begin{pmatrix}%s\end{pmatrix}' % '\\\\ \n'.join(ret) def ndarray_to_latex_parts(ndarr, fmtfun=lambda x: format(x, '.2f'), dim=()): if isinstance(fmtfun, str): fmt = fmtfun fmtfun = lambda x: format(x, fmt) if ndarr.ndim == 1: return [vector_to_latex(ndarr, fmtfun)] if ndarr.ndim == 2: return [matrix_to_latex(ndarr, fmtfun)] else: ret = [] if ndarr.ndim == 3: header = ('arr[%s,' % ','.join('%d' % d for d in dim)) + '%d,:,:]' for elno, el in enumerate(ndarr): ret += [header % elno + ' = ' + matrix_to_latex(el, fmtfun)] else: for elno, el in enumerate(ndarr): ret += ndarray_to_latex_parts(el, fmtfun, dim + (elno, )) return ret def ndarray_to_latex(ndarr, fmtfun=lambda x: format(x, '.2f'), dim=()): return '\n'.join(ndarray_to_latex_parts(ndarr, fmtfun, dim))