Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a static array of structures:

struct CommandStruct
{
    char* data;
    unsigned ans_size;
};

static const CommandStruct commands[] =
{
    { "Some literal", 28 },
    { "Some other literal", 29 },
    { "Yet another literal", 8 },
};

And I want the strings to be 16-byte aligned. Is it possible to achieve it directly? I might get away with defining each literal separately, like __declspec(align(16)) static const char some_command_id[] = "my literal", but that's a mess. I need all initialization in a single block of code.

share|improve this question
    
Do you want the pointers to character sequences aligned (the char* data) or the actual chars? –  Liosan Feb 25 at 8:58
    
Of course the chars. The first char must be at 16-byte boundary. –  panda-34 Feb 25 at 9:03
    
User-defined literals? Alignment support is new in C++11 and needs a little verbosity, so you may need your own "aligned string" class. –  Kerrek SB Feb 25 at 9:53
1  
A practical solution is to copy them to 16-byte aligned storage. –  Cheers and hth. - Alf Feb 25 at 11:28
    
Is there a reason why you want them to be 16 byte aligned instead of platform specific alignment? –  aks Feb 25 at 13:14

2 Answers 2

up vote 2 down vote accepted

With C++11, following may help: https://ideone.com/IDEdY0

#include <cstdint>

// Sequence of char
template <char...Cs> struct char_sequence
{
    template <char C> using push_back = char_sequence<Cs..., C>;
};

// Remove all chars from char_sequence from '\0'
template <typename, char...> struct strip_sequence;

template <char...Cs>
struct strip_sequence<char_sequence<>, Cs...>
{
    using type = char_sequence<Cs...>;
};

template <char...Cs, char...Cs2>
struct strip_sequence<char_sequence<'\0', Cs...>, Cs2...>
{
    using type = char_sequence<Cs2...>;
};

template <char...Cs, char C, char...Cs2>
struct strip_sequence<char_sequence<C, Cs...>, Cs2...>
{
    using type = typename strip_sequence<char_sequence<Cs...>, Cs2..., C>::type;
};

// struct to create a aligned char array
template <std::size_t Alignment, typename chars> struct aligned_string;

template <std::size_t Alignment, char...Cs>
struct aligned_string<Alignment, char_sequence<Cs...>>
{
    alignas(Alignment) static constexpr char str[sizeof...(Cs)] = {Cs...};
};

template <std::size_t Alignment, char...Cs>
alignas(Alignment) constexpr
char aligned_string<Alignment, char_sequence<Cs...>>::str[sizeof...(Cs)];

// helper to get the i_th character (`\0` for out of bound)
template <std::size_t I, std::size_t N>
constexpr char at(const char (&a)[N]) { return I < N ? a[I] : '\0'; }

// helper to check if the c-string will not be truncated
template <std::size_t max_size, std::size_t N>
constexpr bool check_size(const char (&)[N])
{
    static_assert(N <= max_size, "string too long");
    return N <= max_size;
}

// Helper macros to build char_sequence from c-string
#define PUSH_BACK_8(S, I) \
    ::push_back<at<(I) + 0>(S)>::push_back<at<(I) + 1>(S)> \
    ::push_back<at<(I) + 2>(S)>::push_back<at<(I) + 3>(S)> \
    ::push_back<at<(I) + 4>(S)>::push_back<at<(I) + 5>(S)> \
    ::push_back<at<(I) + 6>(S)>::push_back<at<(I) + 7>(S)>

#define PUSH_BACK_32(S, I) \
        PUSH_BACK_8(S, (I) + 0) PUSH_BACK_8(S, (I) + 8) \
        PUSH_BACK_8(S, (I) + 16) PUSH_BACK_8(S, (I) + 24)

#define PUSH_BACK_128(S, I) \
    PUSH_BACK_32(S, (I) + 0) PUSH_BACK_32(S, (I) + 32) \
    PUSH_BACK_32(S, (I) + 64) PUSH_BACK_32(S, (I) + 96)

// Macro to create char_sequence from c-string (limited to 128 chars)
#define MAKE_CHAR_SEQUENCE(S) \
    strip_sequence<char_sequence<> \
    PUSH_BACK_128(S, 0) \
    >::type::template push_back<check_size<128>(S) ? '\0' : '\0'>

// Macro to return an aligned c-string
#define MAKE_ALIGNED_STRING(ALIGNMENT, S) \
    aligned_string<ALIGNMENT, MAKE_CHAR_SEQUENCE(S)>::str

And so you have:

static const CommandStruct commands[] =
{
    { MAKE_ALIGNED_STRING(16, "Some literal"), 28 },
    { MAKE_ALIGNED_STRING(16, "Some other literal"), 29 },
    { MAKE_ALIGNED_STRING(16, "Yet another literal"), 8 },
};
share|improve this answer
    
Does it work in clang for you? It returns: warning: array index 125 is past the end of the array (which contains 6 elements) [-Warray-bounds] for me –  RushPL May 15 at 11:25
    
@RushPL: the static_assert for address is not supported, but else it works (coliru.stacked-crooked.com/a/5dc1419e638a9776). –  Jarod42 May 15 at 11:32
    
It turns out that it was triggered by a different error and was a false positive. Thanks for a prompt comment. –  RushPL May 15 at 12:26
    
Since I consider your answer here a work of genius would you have any idea about my question? stackoverflow.com/q/24152042/403571 –  RushPL Jun 10 at 22:55

Having browsed through boost a bit, I've managed to cook up something which just automates separate literals construction, (I also make enum of all the array's elements):

#define CMD_TUPLE ( \
    (cmdCommandOne, "The first command", 1900),\
    (cmdCommandTwo, "The second one",    1),\
    (cmdAnother,    "Another command",   11))

#define CMD_SEQ BOOST_PP_TUPLE_TO_SEQ(CMD_TUPLE)

#define CMD_MAKE_ENUM(r, data, elem) BOOST_PP_TUPLE_ELEM(0, elem),
enum Commands { BOOST_PP_SEQ_FOR_EACH(CMD_MAKE_ENUM, , CMD_SEQ) cmdLast };

#define CMD_MAKE_STRING(r, data, elem) \
    __declspec(align(16)) static const char \
    BOOST_PP_CAT(cmd_, BOOST_PP_TUPLE_ELEM(0, elem))[] = BOOST_PP_TUPLE_ELEM(1, elem);
BOOST_PP_SEQ_FOR_EACH(CMD_MAKE_STRING, , CMD_SEQ)

#define CMD_MAKE_ARRAY(r, data, elem) \
    { BOOST_PP_CAT(cmd_, BOOST_PP_TUPLE_ELEM(0, elem)), \
    BOOST_PP_SEQ_ENUM(BOOST_PP_SEQ_REST_N(2, BOOST_PP_TUPLE_TO_SEQ(elem))) },
static const CommandStruct commands[] = {
    BOOST_PP_SEQ_FOR_EACH(CMD_MAKE_ARRAY, , CMD_SEQ)
};
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.