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How could one convert a string to upper case. The examples I have found from googling only have to deal with chars.

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23 Answers 23

up vote 171 down vote accepted

Boost string algorithms:

#include <boost/algorithm/string.hpp>
#include <string>

std::string str = "Hello World";

boost::to_upper(str);

std::string newstr = boost::to_upper_copy<std::string>("Hello World");
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5  
This also has the benefit of i18n, where ::toupper is most likely assumes ASCII. – Ben Straub Mar 9 '10 at 22:07
4  
Your last line does not compile - you have to change to something like: std::string newstr(boost::to_upper_copy<std::string>("Hello World")); – maxschlepzig Mar 18 '14 at 11:23
6  
this should not be the accepted answer since it requires boost, or the title should be changed. – Andrea Nov 25 '15 at 11:53
    
This appears to perform extremely badly with g++ 5.2 -O3, and Boost 1.58 (like 30x worse than calling glibc's toupper in a loop.) There's a dynamic_cast of the locale that doesn't get hoisted out of the per-char loop. See my answer. On the plus side, this may be properly UTF-8 aware, but the slowdown doesn't come from handling UTF-8; it comes from using a dynamic_cast to re-check the locale every character. – Peter Cordes May 12 at 11:37
1  
yes, i am going to install boost just for to_upper... excellent idea! </sarcasm> :) – thang May 31 at 16:04
#include <algorithm>
#include <string>

std::string str = "Hello World";
std::transform(str.begin(), str.end(),str.begin(), ::toupper);
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6  
Actually, toupper() can be implemented as a macro. This may cause an issue. – dirkgently Apr 9 '09 at 17:43
1  
Good point dirk (unfortunately). Otherwise I think this is certainly the cleanest and clearest way. – j_random_hacker Apr 9 '09 at 17:44
3  
a bind(::toupper, construct<unsigned char>(_1)) with boost.lambda will serve perfectly fine i think. – Johannes Schaub - litb Apr 9 '09 at 18:49
3  
This approach works fine for ASCII, but fails for multi-byte character encodings, or for special casing rules like German 'ß'. – dan04 Aug 1 '10 at 4:32
8  
I changed the accepted answer to the one using the boost libraries, because it was faster (in my informal testing), easier to use, and doesn't have the the problems associated with this solution. Still a good solution for instances where boost can't be used. – OrangeAlmondSoap Jan 25 '11 at 3:48

Short solution using C++11 and toupper().

for (auto & c: str) c = toupper(c);
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struct convert {
   void operator()(char& c) { c = toupper((unsigned char)c); }
};

// ... 
string uc_str;
for_each(uc_str.begin(), uc_str.end(), convert());

Note: A couple of problems with the top solution:

21.5 Null-terminated sequence utilities

The contents of these headers shall be the same as the Standard C Library headers <ctype.h>, <wctype.h>, <string.h>, <wchar.h>, and <stdlib.h> [...]

  • Which means that the cctype members may well be macros not suitable for direct consumption in standard algorithms.

  • Another problem with the same example is that it does not cast the argument or verify that this is non-negative; this is especially dangerous for systems where plain char is signed. (The reason being: if this is implemented as a macro it will probably use a lookup table and your argument indexes into that table. A negative index will give you UB.)

share|improve this answer
    
The normal cctype members are macros. I remember reading that they also had to be functions, although I don't have a copy of the C90 standard and don't know if it was explicitly stated or not. – David Thornley Apr 9 '09 at 18:08
1  
they have to be functions in C++ - even if C allows them to be macros. i agree with your second point about the casting though. the top solution could pass negative values and cause UB with that. that's the reason i didn't vote it up (but i didn't vote it down either) :) – Johannes Schaub - litb Apr 9 '09 at 18:32
1  
standard quote must not be missing: 7.4.2.2/1 (poor litb, that's referencing a C99 TC2 draft only), and C++ 17.4.1.2/6 in the glory c++98 standard. – Johannes Schaub - litb Apr 9 '09 at 18:34
1  
(note the foot-note to it: "This disallows the common practice of providing a masking macro.... blah blupp .. only way to do it in C++ is to provide a extern inline function.") :) – Johannes Schaub - litb Apr 9 '09 at 18:35
1  
... that's achieved by this trickery: stackoverflow.com/questions/650461/… – Johannes Schaub - litb Apr 9 '09 at 19:28

Do you have ASCII or International characters in strings?

If it's the latter case, "uppercasing" is not that simple, and it depends on the used alphabet. There are bicameral and unicameral alphabets. Only bicameral alphabets have different characters for upper and lower case. Also, there are composite characters, like Latin capital letter 'DZ' (\u01F1 'DZ') which use the so called title case. This means that only the first character (D) gets changed.

I suggest you look into ICU, and difference between Simple and Full Case Mappings. This might help:

http://userguide.icu-project.org/transforms/casemappings

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6  
Or the German eszet (sp?), the thing that looks like the Greek letter beta, and means "ss". There is no single German character that means "SS", which is the uppercase equivalent. The German word for "street", when uppercased, gets one character longer. – David Thornley Apr 9 '09 at 18:11
5  
Another special case is the Greek letter sigma (Σ), which has two lowercase versions, depending on whether it's at the end of a word (ς) or not (σ). And then there are language specific rules, like Turkish having the case mapping I↔ı and İ↔i. – dan04 Aug 1 '10 at 4:30
    
"Uppercasing" is called case folding. – Columbo Jul 13 '15 at 15:48
string StringToUpper(string strToConvert)
{
   for (std::string::iterator p = strToConvert.begin(); strToConvert.end() != p; ++p)
       *p = toupper(*p);

   return p;
}

Or,

string StringToUpper(string strToConvert)
{
    std::transform(strToConvert.begin(), strToConvert.end(), strToConvert.begin(), ::toupper);

    return strToConvert;
}
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4  
if you don't have access to boost the second solution is probably the best you can get. what do the stars ** after the parameters on the first solution do? – Sam Brinck Aug 7 '12 at 21:45
1  
I'm pretty sure the ** is a typo left over from trying to use bold font in the code syntax. – MasterHD Oct 26 '15 at 15:35

Simpler and faster if you use only ASCII characters:

for(i=0;str[i]!=0;i++)
  if(str[i]<=122 && str[i]>=97)
    str[i]-=32;
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1  
The question is tagged as C++, but you wrote a C answer here. (I'm not one of the downvoters.) – hkBattousai Aug 18 '13 at 17:11
2  
I wrote a C answer AND a C++ answer here beacuse C++ is written to be fully compatible with C sources, so any C solution is also a C++ correct solution – Luke Aug 19 '13 at 8:54
    
But it is so much better to give an answer which respects C++ way. – Dmitriy Yurchenko Jan 2 '14 at 2:48
4  
It is less nice, but faster, smaller and 100% correct – Luke Jan 2 '14 at 10:16

Use a lambda.

std::string s("change my case");

auto to_upper = [] (char_t ch) { return std::use_facet<std::ctype<char_t>>(std::locale()).toupper(ch); };

std::transform(s.begin(), s.end(), s.begin(), to_upper);
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1  
Byron, don't worry about the other comments. It is quite ok to answer old questions with new (modern) solution as you did. – Kyberias Dec 28 '14 at 16:30
typedef std::string::value_type char_t;

char_t up_char( char_t ch )
{
    return std::use_facet< std::ctype< char_t > >( std::locale() ).toupper( ch );
}

std::string toupper( const std::string &src )
{
    std::string result;
    std::transform( src.begin(), src.end(), std::back_inserter( result ), up_char );
    return result;
}

const std::string src  = "test test TEST";

std::cout << toupper( src );
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wouldnt recommend a back_inserter as you already know the length; use std::string result(src.size()); std::transform( src.begin(), src.end(), result.begin(), up_char ); – Viktor Sehr Mar 9 '10 at 21:24
    
Altough I am sure you know this. – Viktor Sehr Mar 9 '10 at 21:25
    
@Viktor Sehr, @bayda: I know this is 2 years old, but why not get the best of both worlds. Use reserve and back_inserter (making so the string is only copied once). inline std::string to_lower(const std::string &s) { std::string result; result.reserve(s.size()); std::transform(s.begin(), s.end(), std::back_inserter( result ), static_cast<int(*)(int)>(std::tolower)); return result; } – Evan Teran Nov 1 '11 at 19:58
//works for ASCII -- no clear advantage over what is already posted...

std::string toupper(const std::string & s)
{
    std::string ret(s.size(), char());
    for(unsigned int i = 0; i < s.size(); ++i)
        ret[i] = (s[i] <= 'z' && s[i] >= 'a') ? s[i]-('a'-'A') : s[i];
    return ret;
}
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s.size() is clearly not of type 'unsigned int' – malat Feb 5 '14 at 12:32
    
s.size() is of type std::size_t which, AFAIK could very well be unsigned int depending on the implementation – PorkyBrain Jul 31 '14 at 13:09
    
I don't think there are any modern implementations in which the result of std::string::size is signed. Given that, both semantically and practically, there's no such thing as a negative size, I'm going to go with size_t being at least a 32-bit unsigned integer. – user1329482 Oct 4 '15 at 18:21
    
There's no reason not to write for (size_t i = 0 .... There's also no good reason to make it so hard to read. This also copies the string first and then loop over it. @Luke's answer is better in some ways, except for not taking advantage of 'a' character constants. – Peter Cordes Apr 18 at 7:17
inline void strtoupper(char* str)
{
    while (*str)
    {
        *str = toupper(*str);
        str++;
    }
}
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try the toupper() function (#include <ctype.h>). it accepts characters as arguments, strings are made up of characters, so you'll have to iterate over each individual character that when put together comprise the string

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std::string value;
for (std::string::iterator p = value.begin(); value.end() != p; ++p)
    *p = toupper(*p);
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The following works for me.

void  toUpperCase(std::string& str)
{
    std::transform(str.begin(), str.end(), str.begin(), ::toupper);
}

int main()
{
   std::string str = "hello";
   toUpperCase(&str);
}
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Here is the latest code with C++11

std::string cmd = "Hello World";
for_each(cmd.begin(), cmd.end(), [](char& in){ in = ::toupper(in); });
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not sure there is a built in function. Try this:

Include either the ctype.h OR cctype libraries, as well as the stdlib.h as part of the preprocessor directives.

string StringToUpper(string strToConvert)
{//change each element of the string to upper case
   for(unsigned int i=0;i<strToConvert.length();i++)
   {
      strToConvert[i] = toupper(strToConvert[i]);
   }
   return strToConvert;//return the converted string
}

string StringToLower(string strToConvert)
{//change each element of the string to lower case
   for(unsigned int i=0;i<strToConvert.length();i++)
   {
      strToConvert[i] = tolower(strToConvert[i]);
   }
   return strToConvert;//return the converted string
}
share|improve this answer
    
.length() is not of type 'unsigned int' – malat Feb 5 '14 at 12:32

This problem is vectorizable with SIMD for the ASCII character set.


Speedup comparisons:

Preliminary testing with x86-64 gcc 5.2 -O3 -march=native on a Core2Duo (Merom). The same string of 120 characters (mixed lowercase and non-lowercase ASCII), converted in a loop 40M times (with no cross-file inlining, so the compiler can't optimize away or hoist any of it out of the loop). Same source and dest buffers, so no malloc overhead or memory/cache effects: data is hot in L1 cache the whole time, and we're purely CPU-bound.

  • boost::to_upper_copy<char*, std::string>(): 198.0s. Yes, Boost 1.58 on Ubuntu 15.10 is really this slow. I profiled and single-stepped the asm in a debugger, and it's really, really bad: there's a dynamic_cast of a locale variable happening per character!!! (dynamic_cast takes multiple calls to strcmp). This happens with LANG=C and with LANG=en_CA.UTF-8.

    I didn't test using a RangeT other than std::string. Maybe the other form of to_upper_copy optimizes better, but I think it will always new/malloc space for the copy, so it's harder to test. Maybe something I did differs from a normal use-case, and maybe normally stopped g++ can hoist the locale setup stuff out of the per-character loop. My loop reading from a std::string and writing to a char dstbuf[4096] makes sense for testing.

  • loop calling glibc toupper: 6.67s (not checking the int result for potential multi-byte UTF-8, though. This matters for Turkish.)

  • ASCII-only loop: 8.79s (my baseline version for the results below.) Apparently a table-lookup is faster than a cmov, with the table hot in L1 anyway.
  • ASCII-only auto-vectorized: 2.51s. (120 chars is half way between worst case and best case, see below)
  • ASCII-only manually vectorized: 1.35s

See also this question about toupper() being slow on Windows when a locale is set.


I was shocked that Boost is an order of magnitude slower than the other options. I double-checked that I had -O3 enabled, and even single-stepped the asm to see what it was doing. It's almost exactly the same speed with clang++ 3.8. It has huge overhead inside the per-character loop. The perf record / report result (for the cycles perf event) is:

  32.87%  flipcase-clang-  libstdc++.so.6.0.21   [.] _ZNK10__cxxabiv121__vmi_class_type_info12__do_dyncastElNS_17__class_type_info10__sub_kindEPKS1_PKvS4_S6_RNS1_16
  21.90%  flipcase-clang-  libstdc++.so.6.0.21   [.] __dynamic_cast                                                                                                 
  16.06%  flipcase-clang-  libc-2.21.so          [.] __GI___strcmp_ssse3                                                                                            
   8.16%  flipcase-clang-  libstdc++.so.6.0.21   [.] _ZSt9use_facetISt5ctypeIcEERKT_RKSt6locale                                                                     
   7.84%  flipcase-clang-  flipcase-clang-boost  [.] _Z16strtoupper_boostPcRKNSt7__cxx1112basic_stringIcSt11char_traitsIcESaIcEEE                                   
   2.20%  flipcase-clang-  libstdc++.so.6.0.21   [.] strcmp@plt                                                                                                     
   2.15%  flipcase-clang-  libstdc++.so.6.0.21   [.] __dynamic_cast@plt                                                                                             
   2.14%  flipcase-clang-  libstdc++.so.6.0.21   [.] _ZNKSt6locale2id5_M_idEv                                                                                       
   2.11%  flipcase-clang-  libstdc++.so.6.0.21   [.] _ZNKSt6locale2id5_M_idEv@plt                                                                                   
   2.08%  flipcase-clang-  libstdc++.so.6.0.21   [.] _ZNKSt5ctypeIcE10do_toupperEc                                                                                  
   2.03%  flipcase-clang-  flipcase-clang-boost  [.] _ZSt9use_facetISt5ctypeIcEERKT_RKSt6locale@plt                                                                 
   0.08% ...

Autovectorization

Gcc and clang will only auto-vectorize loops when the iteration count is known ahead of the loop. (i.e. search loops like plain-C implementation of strlen won't autovectorize.)

Thus, for strings small enough to fit in cache, we get a significant speedup for strings ~128 chars long from doing strlen first. This won't be necessary for explicit-length strings (like C++ std::string).

// char, not int, is essential: otherwise gcc unpacks to vectors of int!  Huge slowdown.
char ascii_toupper_char(char c) {
    return ('a' <= c && c <= 'z') ? c^0x20 : c;    // ^ autovectorizes to PXOR: runs on more ports than paddb
}

// gcc can only auto-vectorize loops when the number of iterations is known before the first iteration.  strlen gives us that
size_t strtoupper_autovec(char *dst, const char *src) {
    size_t len = strlen(src);
    for (size_t i=0 ; i<len ; ++i) {
        dst[i] = ascii_toupper_char(src[i]);  // gcc does the vector range check with psubusb / pcmpeqb instead of pcmpgtb
    }
    return len;
}

Any decent libc will have an efficient strlen that's much faster than looping a byte at a time, so separate vectorized strlen and toupper loops are faster.

Baseline: a loop that checks for a terminating 0 on the fly.

Times for 40M iterations, on a Core2 (Merom) 2.4GHz. gcc 5.2 -O3 -march=native. (Ubuntu 15.10). dst != src (so we make a copy), but they don't overlap (and aren't nearby). Both are aligned.

  • 15 char string: baseline: 1.08s. autovec: 1.34s
  • 16 char string: baseline: 1.16s. autovec: 1.52s
  • 127 char string: baseline: 8.91s. autovec: 2.98s // non-vector cleanup has 15 chars to process
  • 128 char string: baseline: 9.00s. autovec: 2.06s
  • 129 char string: baseline: 9.04s. autovec: 2.07s // non-vector cleanup has 1 char to process

Some results are a bit different with clang.

The microbenchmark loop that calls the function is in a separate file. Otherwise it inlines and strlen() gets hoisted out of the loop, and it runs dramatically faster, esp. for 16 char strings (0.187s).

This has the major advantage that gcc can auto-vectorize it for any architecture, but the major disadvantage that it's slower for the usually-common case of small strings.


So there are big speedups, but compiler auto-vectorization doesn't make great code, esp. for cleanup of the last up-to-15 characters.

Manual vectorization with SSE intrinsics:

Based on my case-flip function that inverts the case of every alphabetic character. It takes advantage of the "unsigned compare trick", where you can do low < a && a <= high with a single unsigned comparison by range shifting, so that any value less than low wraps to a value that's greater than high. (This works if low and high aren't too far apart.)

SSE only has a signed compare-greater, but we can still use the "unsigned compare" trick by range-shifting to the bottom of the signed range: Subtract 'a'+128, so the alphabetic characters range from -128 to -128+25 (-128+'z'-'a')

Note that adding 128 and subtracting 128 are the same thing for 8bit integers. There's nowhere for the carry to go, so it's just xor (carryless add), flipping the high bit.

#include <immintrin.h>

__m128i upcase_si128(__m128i src) {
    // The above 2 paragraphs were comments here
    __m128i rangeshift = _mm_sub_epi8(src, _mm_set1_epi8('a'+128));
    __m128i nomodify   = _mm_cmpgt_epi8(rangeshift, _mm_set1_epi8(-128 + 25));  // 0:lower case   -1:anything else (upper case or non-alphabetic).  25 = 'z' - 'a'

    __m128i flip  = _mm_andnot_si128(nomodify, _mm_set1_epi8(0x20));            // 0x20:lcase    0:non-lcase

    // just mask the XOR-mask so elements are XORed with 0 instead of 0x20
    return          _mm_xor_si128(src, flip);
    // it's easier to xor with 0x20 or 0 than to AND with ~0x20 or 0xFF
}

Given this function that works for one vector, we can call it in a loop to process a whole string. Since we're already targeting SSE2, we can do a vectorized end-of-string check at the same time.

We can also do much better for the "cleanup" of the last up-to-15 bytes left over after doing vectors of 16B: upper-casing is idempotent, so re-processing some input bytes is fine. We do an unaligned load of the last 16B of the source, and store it into the dest buffer overlapping the last 16B store from the loop.

The only time this doesn't work is when the whole string is under 16B: Even when dst=src, non-atomic read-modify-write is not the same thing as not touching some bytes at all, and can break multithreaded code.

We have a scalar loop for that, and also to get src aligned. Since we don't know where the terminating 0 will be, an unaligned load from src might cross into the next page and segfault. If we need any bytes in an aligned 16B chunk, it's always safe to load the whole aligned 16B chunk.

Full source: in a github gist.

// FIXME: doesn't always copy the terminating 0.
// microbenchmarks are for this version of the code (with _mm_store in the loop, instead of storeu, for Merom).
size_t strtoupper_sse2(char *dst, const char *src_begin) {
    const char *src = src_begin;
    // scalar until the src pointer is aligned
    while ( (0xf & (uintptr_t)src) && *src ) {
        *(dst++) = ascii_toupper(*(src++));
    }

    if (!*src)
        return src - src_begin;

    // current position (p) is now 16B-aligned, and we're not at the end
    int zero_positions;
    do {
        __m128i sv = _mm_load_si128( (const __m128i*)src );
        // TODO: SSE4.2 PCMPISTRI or PCMPISTRM version to combine the lower-case and '\0' detection?

        __m128i nullcheck = _mm_cmpeq_epi8(_mm_setzero_si128(), sv);
        zero_positions = _mm_movemask_epi8(nullcheck);
        // TODO: unroll so the null-byte check takes less overhead
        if (zero_positions)
            break;

        __m128i upcased = upcase_si128(sv);   // doing this before the loop break lets gcc realize that the constants are still in registers for the unaligned cleanup version.  But it leads to more wasted insns in the early-out case

        _mm_storeu_si128((__m128i*)dst, upcased);
        //_mm_store_si128((__m128i*)dst, upcased);  // for testing on CPUs where storeu is slow
        src += 16;
        dst += 16;
    } while(1);

    // handle the last few bytes.  Options: scalar loop, masked store, or unaligned 16B.
    // rewriting some bytes beyond the end of the string would be easy,
    // but doing a non-atomic read-modify-write outside of the string is not safe.
    // Upcasing is idempotent, so unaligned potentially-overlapping is a good option.

    unsigned int cleanup_bytes = ffs(zero_positions) - 1;  // excluding the trailing null
    const char* last_byte = src + cleanup_bytes;  // points at the terminating '\0'

    // FIXME: copy the terminating 0 when we end at an aligned vector boundary
    // optionally special-case cleanup_bytes == 15: final aligned vector can be used.
    if (cleanup_bytes > 0) {
        if (last_byte - src_begin >= 16) {
            // if src==dest, this load overlaps with the last store:  store-forwarding stall.  Hopefully OOO execution hides it
            __m128i sv = _mm_loadu_si128( (const __m128i*)(last_byte-15) ); // includes the \0
            _mm_storeu_si128((__m128i*)(dst + cleanup_bytes - 15), upcase_si128(sv));
        } else {
            // whole string less than 16B
            // if this is common, try 64b or even 32b cleanup with movq / movd and upcase_si128
#if 1
            for (unsigned int i = 0 ; i <= cleanup_bytes ; ++i) {
                dst[i] = ascii_toupper(src[i]);
            }
#else
            // gcc stupidly auto-vectorizes this, resulting in huge code bloat, but no measurable slowdown because it never runs
            for (int i = cleanup_bytes - 1 ;  i >= 0 ; --i) {
                dst[i] = ascii_toupper(src[i]);
            }
#endif
        }
    }

    return last_byte - src_begin;
}

Times for 40M iterations, on a Core2 (Merom) 2.4GHz. gcc 5.2 -O3 -march=native. (Ubuntu 15.10). dst != src (so we make a copy), but they don't overlap (and aren't nearby). Both are aligned.

  • 15 char string: baseline: 1.08s. autovec: 1.34s. manual: 1.29s
  • 16 char string: baseline: 1.16s. autovec: 1.52s. manual: 0.335s
  • 31 char string: manual: 0.479s
  • 127 char string: baseline: 8.91s. autovec: 2.98s. manual: 0.925s
  • 128 char string: baseline: 9.00s. autovec: 2.06s. manual: 0.931s
  • 129 char string: baseline: 9.04s. autovec: 2.07s. manual: 1.02s

(Actually timed with _mm_store in the loop, not _mm_storeu, because storeu is slower on Merom even when the address is aligned. It's fine on Nehalem and later. I've also left the code as-is for now, instead of fixing the failure to copy the terminating 0 in some cases, because I don't want to re-time everything.)

So for short strings longer than 16B, this is dramatically faster than auto-vectorized. Lengths one-less-than-a-vector-width don't present a problem. They might be a problem when operating in-place, because of a store-forwarding stall. (But note that it's still fine to process our own output, rather than the original input, because toupper is idempotent).

There's a lot of scope for tuning this for different use-cases, depending on what the surrounding code wants, and the target microarchitecture. Getting the compiler to emit nice code for the cleanup portion is tricky. Using ffs(3) (which compiles to bsf or tzcnt on x86) seems to be good, but obviously that bit needs a re-think since I noticed a bug after writing up most of this answer (see the FIXME comments).

Vector speedups for even smaller strings can be obtained with movq or movd loads/stores. Customize as necessary for your use-case.


UTF-8:

We can detect when our vector has any bytes with the high bit set, and in that case fall back to a scalar utf-8-aware loop for that vector. The dst point can advance by a different amount than the src pointer, but once we get back to an aligned src pointer, we'll still just do unaligned vector stores to dst.

For text that's UTF-8, but mostly consists of the ASCII subset of UTF-8, this can be good: high performance in the common case with correct behaviour in all cases. When there's a lot of non-ASCII, it will probably be worse than staying in the scalar UTF-8 aware loop all the time, though.

Making English faster at the expense of other languages is not a future-proof decision if the downside is significant.


Locale-aware:

In the Turkish locale (tr_TR), the correct result from toupper('i') is 'İ' (U0130), not 'I' (plain ASCII). See Martin Bonner's comments on a question about tolower() being slow on Windows.

We can also check for an exception-list and fallback to scalar there, like for multi-byte UTF8 input characters.

With this much complexity, SSE4.2 PCMPISTRM or something might be able to do a lot of our checks in one go.

share|improve this answer

Without using any libraries:

std::string YourClass::Uppercase(const std::string & Text)
{
    std::string UppperCaseString;
    UppperCaseString.reserve(Text.size());
    for (std::string::const_iterator it=Text.begin(); it<Text.end(); ++it)
    {
        UppperCaseString.push_back(((0x60 < *it) && (*it < 0x7B)) ? (*it - static_cast<char>(0x20)) : *it);
    }
    return UppperCaseString;
}
share|improve this answer

If you are only concerned with 8 bit characters (which all other answers except Milan Babuškov assume as well) you can get the fastest speed by generating a look-up table at compile time using metaprogramming. On ideone.com this runs 7x faster than the library function and 3x faster than a hand written version (http://ideone.com/sb1Rup). It is also customizeable through traits with no slow down.

template<int ...Is>
struct IntVector{
using Type = IntVector<Is...>;
};

template<typename T_Vector, int I_New>
struct PushFront;
template<int ...Is, int I_New>
struct PushFront<IntVector<Is...>,I_New> : IntVector<I_New,Is...>{};

template<int I_Size, typename T_Vector = IntVector<>>
struct Iota : Iota< I_Size-1, typename PushFront<T_Vector,I_Size-1>::Type> {};
template<typename T_Vector>
struct Iota<0,T_Vector> : T_Vector{};

template<char C_In>
struct ToUpperTraits {
    enum { value = (C_In >= 'a' && C_In <='z') ? C_In - ('a'-'A'):C_In };
};

template<typename T>
struct TableToUpper;
template<int ...Is>
struct TableToUpper<IntVector<Is...>>{
    static char at(const char in){
        static const char table[] = {ToUpperTraits<Is>::value...};
        return table[in];
    }
};

int tableToUpper(const char c){
    using Table = TableToUpper<typename Iota<256>::Type>;
    return Table::at(c);
}

with use case:

std::transform(in.begin(),in.end(),out.begin(),tableToUpper);

For an in depth (many page) decription of how it works allow me to shamelessly plug my blog: http://metaporky.blogspot.de/2014/07/part-4-generating-look-up-tables-at.html

share|improve this answer
template<size_t size>
char* toupper(char (&dst)[size], const char* src) {
    // generate mapping table once
    static char maptable[256];
    static bool mapped;
    if (!mapped) {
        for (char c = 0; c < 256; c++) {
            if (c >= 'a' && c <= 'z')
                maptable[c] = c & 0xdf;
            else
                maptable[c] = c;
        }
        mapped = true;
    }

    // use mapping table to quickly transform text
    for (int i = 0; *src && i < size; i++) {
        dst[i] = maptable[*(src++)];
    }
    return dst;
}
share|improve this answer

ALL of these solutions on this page are harder than they need to be.

Do this

RegName = "SomE StRing That you wAnt ConvErTed";
NameLength = RegName.Size();
for (int forLoop = 0; forLoop < NameLength; ++forLoop)
{
     RegName[forLoop] = tolower(RegName[forLoop]);
}

RegName is your string. Get your string size don't use string.size() as your actual tester, very messy and can cause issues. then. the most basic for loop.

remember string size returns the delimiter too so use < and not <= in your loop test.

output will be: some string that you want converted

share|improve this answer
4  
I don't see how this is simpler than the boost::toupper solution. Can you elaborate? – tr9sh Feb 14 '12 at 23:11
1  
There are already lots of simple tolower loops, and most of them use standard loop variable names like i, not the weird forLoop. – Peter Cordes Apr 18 at 7:24

I use this solution. I know you're not supposed to modify that data area.... but I think that's mostly for buffer overrun bugs and null character.... upper casing things isn't the same.

void to_upper(const std::string str) {
    std::string::iterator it;
    int i;
    for ( i=0;i<str.size();++i ) {
        ((char *)(void *)str.data())[i]=toupper(((char *)str.data())[i]);
    }
}
share|improve this answer
    
I know you're not supposed to modify that data area - what data area are you not supposed to modify? – user93353 Jul 22 '13 at 21:09
2  
This is late, but what on earth? That crazy line can be replaced with str[i] = toupper(str[i]); perfectly fine (well, not perfectly fine, but it fixes most of the things wrong). – chris Jun 9 '14 at 1:14

In all the machines I tested, it was faster. Perhaps because he is not concerned with a very wide range of characters. Or because using switch() it makes a jump table, do not know how it works in the assembly ... just know that is faster :P

string Utils::String::UpperCase(string CaseString) {
    for (unsigned short i = 0, tamanho = CaseString.length(); i < tamanho; i++) {
        switch (CaseString[i]) {
            case 'a':
                CaseString[i] = 'A';
                break;
            case 'b':
                CaseString[i] = 'B';
                break;
            case 'c':
                CaseString[i] = 'C';
                break;
            case 'd':
                CaseString[i] = 'D';
                break;
            case 'e':
                CaseString[i] = 'E';
                break;
            case 'f':
                CaseString[i] = 'F';
                break;
            case 'g':
                CaseString[i] = 'G';
                break;
            case 'h':
                CaseString[i] = 'H';
                break;
            case 'i':
                CaseString[i] = 'I';
                break;
            case 'j':
                CaseString[i] = 'J';
                break;
            case 'k':
                CaseString[i] = 'K';
                break;
            case 'l':
                CaseString[i] = 'L';
                break;
            case 'm':
                CaseString[i] = 'M';
                break;
            case 'n':
                CaseString[i] = 'N';
                break;
            case 'o':
                CaseString[i] = 'O';
                break;
            case 'p':
                CaseString[i] = 'P';
                break;
            case 'q':
                CaseString[i] = 'Q';
                break;
            case 'r':
                CaseString[i] = 'R';
                break;
            case 's':
                CaseString[i] = 'S';
                break;
            case 't':
                CaseString[i] = 'T';
                break;
            case 'u':
                CaseString[i] = 'U';
                break;
            case 'v':
                CaseString[i] = 'V';
                break;
            case 'w':
                CaseString[i] = 'W';
                break;
            case 'x':
                CaseString[i] = 'X';
                break;
            case 'y':
                CaseString[i] = 'Y';
                break;
            case 'z':
                CaseString[i] = 'Z';
                break;
        }
    }
    return CaseString;
}
share|improve this answer
    
What advantage does this code have over the other solutions posted? – Konrad Rudolph Mar 9 '10 at 21:27
1  
In all the machines I tested, it was faster. Perhaps because he is not concerned with a very wide range of characters. Or because using switch() it makes a jump table, do not know how it works in the assembly ... just know that is faster :P – osmano807 Mar 10 '10 at 1:59
1  
It seems that here only accept simple answers ... I made this code to the raw performance, and works well for this use. – osmano807 Mar 10 '10 at 18:21
7  
I think this is a case of sacrificing memory for speed. However, don't reinvent the wheel - in fact that code can be shorted to a couple of lines by just adding 32 to the character, assuming you are dealing with the English alphabet. Which a single addition would be infinitely faster than your solution. I won't up or downvote. Brush up on your coding skills a little bit, not saying what you put is a bad thing but I have seen that coding style many times with the CS students in college and it certainly isn't the best. – Nathan Adams Sep 12 '10 at 16:54
1  
Why not just do const char toupptertable[256] = {..., 'A', 'B', ... }; char ch = toupptertable[oldCh];. Once it's in the cache ...zooooom! – Captain Obvlious May 2 '14 at 1:34

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