SeqAn3 3.1.0
The Modern C++ library for sequence analysis.
dna3bs.hpp
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1// -----------------------------------------------------------------------------------------------------
2// Copyright (c) 2006-2021, Knut Reinert & Freie Universität Berlin
3// Copyright (c) 2016-2021, Knut Reinert & MPI für molekulare Genetik
4// This file may be used, modified and/or redistributed under the terms of the 3-clause BSD-License
5// shipped with this file and also available at: https://github.com/seqan/seqan3/blob/master/LICENSE.md
6// -----------------------------------------------------------------------------------------------------
7
13#pragma once
14
15#include <vector>
16
17#include <seqan3/alphabet/nucleotide/nucleotide_base.hpp>
18#include <seqan3/utility/char_operations/transform.hpp>
19
20// ------------------------------------------------------------------
21// dna3bs
22// ------------------------------------------------------------------
23
24namespace seqan3
25{
60class dna3bs : public nucleotide_base<dna3bs, 3>
61{
62private:
64 using base_t = nucleotide_base<dna3bs, 3>;
65
67 friend base_t;
69 friend base_t::base_t;
71
72public:
76 constexpr dna3bs() noexcept = default;
77 constexpr dna3bs(dna3bs const &) noexcept = default;
78 constexpr dna3bs(dna3bs &&) noexcept = default;
79 constexpr dna3bs & operator=(dna3bs const &) noexcept = default;
80 constexpr dna3bs & operator=(dna3bs &&) noexcept = default;
81 ~dna3bs() noexcept = default;
82
83 using base_t::base_t;
85
86private:
88 static constexpr char_type rank_to_char_table[alphabet_size]
89 {
90 'A',
91 'G',
92 'T'
93 };
94
96 static constexpr std::array<rank_type, 256> char_to_rank_table
97 {
98 [] () constexpr
99 {
100 std::array<rank_type, 256> ret{};
101
102 // reverse mapping for characters and their lowercase
103 for (size_t rnk = 0u; rnk < alphabet_size; ++rnk)
104 {
105 ret[rank_to_char_table[rnk]] = rnk;
106 ret[to_lower(rank_to_char_table[rnk])] = rnk;
107 }
108
109 // set C and U equal to T
110 ret['C'] = ret['T']; ret['c'] = ret['t'];
111 ret['U'] = ret['T']; ret['u'] = ret['t'];
112
113 // iupac characters get special treatment, because there is no N
114 ret['R'] = ret['A']; ret['r'] = ret['A']; // A or G becomes A
115 ret['Y'] = ret['T']; ret['y'] = ret['T']; // C or T becomes T
116 ret['S'] = ret['T']; ret['s'] = ret['T']; // C or G becomes T
117 ret['W'] = ret['A']; ret['w'] = ret['A']; // A or T becomes A
118 ret['K'] = ret['G']; ret['k'] = ret['G']; // G or T becomes G
119 ret['M'] = ret['A']; ret['m'] = ret['A']; // A or C becomes A
120 ret['B'] = ret['T']; ret['b'] = ret['T']; // C or G or T becomes T
121 ret['D'] = ret['A']; ret['d'] = ret['A']; // A or G or T becomes A
122 ret['H'] = ret['A']; ret['h'] = ret['A']; // A or C or T becomes A
123 ret['V'] = ret['A']; ret['v'] = ret['A']; // A or C or G becomes A
124
125 return ret;
126 }()
127 };
128
130 static constexpr rank_type rank_complement_table[alphabet_size]
131 {
132 2, // T is complement of 'A'_dna3bs
133 2, // T is complement of 'G'_dna3bs
134 0 // A is complement of 'T'_dna3bs
135 };
136
138 static constexpr rank_type rank_complement(rank_type const rank)
139 {
140 return rank_complement_table[rank];
141 }
142
144 static constexpr char_type rank_to_char(rank_type const rank)
145 {
146 return rank_to_char_table[rank];
147 }
148
150 static constexpr rank_type char_to_rank(char_type const chr)
151 {
152 using index_t = std::make_unsigned_t<char_type>;
153 return char_to_rank_table[static_cast<index_t>(chr)];
154 }
155};
156
157// ------------------------------------------------------------------
158// containers
159// ------------------------------------------------------------------
160
166using dna3bs_vector = std::vector<dna3bs>;
167
168// ------------------------------------------------------------------
169// literals
170// ------------------------------------------------------------------
171inline namespace literals
172{
173
188constexpr dna3bs operator""_dna3bs(char const c) noexcept
189{
190 return dna3bs{}.assign_char(c);
191}
192
202inline dna3bs_vector operator""_dna3bs(char const * s, std::size_t n)
203{
204 dna3bs_vector r;
205 r.resize(n);
206
207 for (size_t i = 0; i < n; ++i)
208 r[i].assign_char(s[i]);
209
210 return r;
211}
213
214} // inline namespace literals
215
216} // namespace seqan3
seqan3::alphabet_base
A CRTP-base that makes defining a custom alphabet easier.
Definition: alphabet_base.hpp:57
seqan3::alphabet_base::assign_char
constexpr derived_type & assign_char(char_type const chr) noexcept
Assign from a character, implicitly converts invalid characters.
Definition: alphabet_base.hpp:165
seqan3::alphabet_base::rank_type
detail::min_viable_uint_t< size - 1 > rank_type
The type of the alphabet when represented as a number (e.g. via to_rank()).
Definition: alphabet_base.hpp:80
seqan3::alphabet_base::alphabet_size
static constexpr detail::min_viable_uint_t< size > alphabet_size
The size of the alphabet, i.e. the number of different values it can take.
Definition: alphabet_base.hpp:203
seqan3::alphabet_base::char_type
std::conditional_t< std::same_as< char_t, void >, char, char_t > char_type
The char representation; conditional needed to make semi alphabet definitions legal.
Definition: alphabet_base.hpp:72
seqan3::dna3bs
The three letter reduced DNA alphabet for bisulfite sequencing mode (A,G,T(=C))..
Definition: dna3bs.hpp:61
seqan3::dna3bs::dna3bs
constexpr dna3bs() noexcept=default
Defaulted.
seqan3::nucleotide_base
A CRTP-base that refines seqan3::alphabet_base and is used by the nucleotides.
Definition: nucleotide_base.hpp:43
seqan3
The main SeqAn3 namespace.
Definition: cigar_operation_table.hpp:2
seqan3::to_lower
constexpr char_type to_lower(char_type const c) noexcept
Converts 'A'-'Z' to 'a'-'z' respectively; other characters are returned as is.
Definition: transform.hpp:81
nucleotide_base.hpp
Provides seqan3::nucleotide_base.
std::vector::resize
T resize(T... args)
transform.hpp
Provides utilities for modifying characters.