18

I'm working on an embedded DSP where speed is crucial, and memory is very short.

At the moment, sprintf uses the most resources of any function in my code. I only use it to format some simple text: %d, %e, %f, %s, nothing with precision or exotic manipulations.

How can I implement a basic sprintf or printf function that would be more suitable for my usage?

  • Entering your topic title in google found a lot of hits here. BTW: you could always roll your own. %e and %f could be a bit harder, but %d and %s are trivial. – wildplasser May 20 '13 at 10:20
  • Following on from @wildplasser comment, do you really have to use floating-point? – Martin James May 20 '13 at 12:12
  • Yes I do, the DSP is used to provide values that are measured through an ADC.. so float is needed. – Gui13 May 20 '13 at 13:11
  • 2
    Well, ADC's usually generate unsigned ints? – Martin James May 20 '13 at 14:03
  • 2
    You don't need floating point if you perform your calculations in fixed point arithmetic – Sylvain Leroux Jun 8 '13 at 18:31
11

This one assumes the existence of an itoa to convert an int to character representation, and an fputs to write out a string to wherever you want it to go.

The floating point output is non-conforming in at least one respect: it makes no attempt at rounding correctly, as the standard requires, so if you have have (for example) a value of 1.234 that is internally stored as 1.2399999774, it'll be printed out as 1.2399 instead of 1.2340. This saves quite a bit of work, and remains sufficient for most typical purposes.

This also supports %c and %x in addition to the conversions you asked about, but they're pretty trivial to remove if you want to get rid of them (and doing so will obviously save a little memory).

#include <stdarg.h>
#include <stdio.h>
#include <string.h>
#include <windows.h>

static void ftoa_fixed(char *buffer, double value);
static void ftoa_sci(char *buffer, double value);

int my_vfprintf(FILE *file, char const *fmt, va_list arg) {

    int int_temp;
    char char_temp;
    char *string_temp;
    double double_temp;

    char ch;
    int length = 0;

    char buffer[512];

    while ( ch = *fmt++) {
        if ( '%' == ch ) {
            switch (ch = *fmt++) {
                /* %% - print out a single %    */
                case '%':
                    fputc('%', file);
                    length++;
                    break;

                /* %c: print out a character    */
                case 'c':
                    char_temp = va_arg(arg, int);
                    fputc(char_temp, file);
                    length++;
                    break;

                /* %s: print out a string       */
                case 's':
                    string_temp = va_arg(arg, char *);
                    fputs(string_temp, file);
                    length += strlen(string_temp);
                    break;

                /* %d: print out an int         */
                case 'd':
                    int_temp = va_arg(arg, int);
                    itoa(int_temp, buffer, 10);
                    fputs(buffer, file);
                    length += strlen(buffer);
                    break;

                /* %x: print out an int in hex  */
                case 'x':
                    int_temp = va_arg(arg, int);
                    itoa(int_temp, buffer, 16);
                    fputs(buffer, file);
                    length += strlen(buffer);
                    break;

                case 'f':
                    double_temp = va_arg(arg, double);
                    ftoa_fixed(buffer, double_temp);
                    fputs(buffer, file);
                    length += strlen(buffer);
                    break;

                case 'e':
                    double_temp = va_arg(arg, double);
                    ftoa_sci(buffer, double_temp);
                    fputs(buffer, file);
                    length += strlen(buffer);
                    break;
            }
        }
        else {
            putc(ch, file);
            length++;
        }
    }
    return length;
}

int normalize(double *val) {
    int exponent = 0;
    double value = *val;

    while (value >= 1.0) {
        value /= 10.0;
        ++exponent;
    }

    while (value < 0.1) {
        value *= 10.0;
        --exponent;
    }
    *val = value;
    return exponent;
}

static void ftoa_fixed(char *buffer, double value) {  
    /* carry out a fixed conversion of a double value to a string, with a precision of 5 decimal digits. 
     * Values with absolute values less than 0.000001 are rounded to 0.0
     * Note: this blindly assumes that the buffer will be large enough to hold the largest possible result.
     * The largest value we expect is an IEEE 754 double precision real, with maximum magnitude of approximately
     * e+308. The C standard requires an implementation to allow a single conversion to produce up to 512 
     * characters, so that's what we really expect as the buffer size.     
     */

    int exponent = 0;
    int places = 0;
    static const int width = 4;

    if (value == 0.0) {
        buffer[0] = '0';
        buffer[1] = '\0';
        return;
    }         

    if (value < 0.0) {
        *buffer++ = '-';
        value = -value;
    }

    exponent = normalize(&value);

    while (exponent > 0) {
        int digit = value * 10;
        *buffer++ = digit + '0';
        value = value * 10 - digit;
        ++places;
        --exponent;
    }

    if (places == 0)
        *buffer++ = '0';

    *buffer++ = '.';

    while (exponent < 0 && places < width) {
        *buffer++ = '0';
        --exponent;
        ++places;
    }

    while (places < width) {
        int digit = value * 10.0;
        *buffer++ = digit + '0';
        value = value * 10.0 - digit;
        ++places;
    }
    *buffer = '\0';
}

void ftoa_sci(char *buffer, double value) {
    int exponent = 0;
    int places = 0;
    static const int width = 4;

    if (value == 0.0) {
        buffer[0] = '0';
        buffer[1] = '\0';
        return;
    }

    if (value < 0.0) {
        *buffer++ = '-';
        value = -value;
    }

    exponent = normalize(&value);

    int digit = value * 10.0;
    *buffer++ = digit + '0';
    value = value * 10.0 - digit;
    --exponent;

    *buffer++ = '.';

    for (int i = 0; i < width; i++) {
        int digit = value * 10.0;
        *buffer++ = digit + '0';
        value = value * 10.0 - digit;
    }

    *buffer++ = 'e';
    itoa(exponent, buffer, 10);
}

int my_printf(char const *fmt, ...) {
    va_list arg;
    int length;

    va_start(arg, fmt);
    length = my_vfprintf(stdout, fmt, arg);
    va_end(arg);
    return length;
}

int my_fprintf(FILE *file, char const *fmt, ...) {
    va_list arg;
    int length;

    va_start(arg, fmt);
    length = my_vfprintf(file, fmt, arg);
    va_end(arg);
    return length;
}


#ifdef TEST 

int main() {

    float floats[] = { 0.0, 1.234e-10, 1.234e+10, -1.234e-10, -1.234e-10 };

    my_printf("%s, %d, %x\n", "Some string", 1, 0x1234);

    for (int i = 0; i < sizeof(floats) / sizeof(floats[0]); i++)
        my_printf("%f, %e\n", floats[i], floats[i]);

    return 0;
}

#endif

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