CloverBootloader/rEFIt_UEFI/cpp_foundation/printf_lite.cpp
2020-03-12 19:16:18 +03:00

1254 lines
36 KiB
C++

//
// printf_lite.hpp
//
// Created by jief the 04 Apr 2019.
// Imported in CLover the 24 Feb 2020
//
/*
This code should be pasted within the files where this function is needed.
This function will not create any code conflicts.
The function call is similar to printf: ardprintf("Test %d %s", 25, "string");
To print the '%' character, use '%%'
This code was first posted on http://arduino.stackexchange.com/a/201
*/
#include "printf_lite.h" // need to include that before testing #if PRINTF_LITE_USB_SUPPORT == 1
#ifdef USE_HAL_DRIVER
#include "stm32f1xx_hal.h"
#if PRINTF_LITE_USB_SUPPORT == 1
#include "usb_device.h"
#include "usbd_cdc_if.h"
#include "printf_lite.h" // need to re-include that after included usbd_cdc_if.h to get definition under defined(__USBD_CDC_IF_H)
#endif
#endif
#ifdef ARDUINO
#include <Arduino.h>
// #include <HardwareSerial.h>
#endif
#ifdef NRF51
#include <app_timer.h>
#include <app_uart.h>
#endif
#if defined(OS_USE_TRACE_ITM) || defined(OS_USE_TRACE_SEMIHOSTING_DEBUG) || defined(OS_USE_TRACE_SEMIHOSTING_STDOUT)
#include <trace_impl.h>
#endif
#include <stdarg.h>
#include <stdint.h>
#include <limits.h>
#include <stdlib.h>
#ifdef __STM32F1xx_HAL_UART_H
extern UART_HandleTypeDef huart1;
#endif
// using int because this is what generate less code. It's a bit more on the stack but it's temporary.
typedef struct {
#if PRINTF_LITE_BUF_SIZE > 1
printf_char_type buf[PRINTF_LITE_BUF_SIZE];
uint8_t bufIdx;
#endif
transmitBufCallBackType transmitBufCallBack;
int inDirective;
int l_modifier;
#if PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
int z_modifier;
#endif
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
int inWidthField;
int width_specifier;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1 || (PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 && PRINTF_LITE_FIELDWIDTH_SUPPORT == 1) // in that case, we need the inPrecisionField to know we are currently ignoring precision field
int inPrecisionField;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
int precision_specifier;
#endif
#if PRINTF_LITE_PADCHAR_SUPPORT == 1
char pad_char;
#endif
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
int *newlinePtr;
int timestamp; // not using bool in case of C compilation
#endif
#if PRINTF_LITE_XSPECIFIER_SUPPORT == 1
int uppercase;
#endif
} PrintfParams;
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
static void print_timestamp(PrintfParams* printfParams);
#endif
static void print_char(printf_char_type c, PrintfParams* printfParams)
{
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
if ( printfParams->newlinePtr )
{
if ( *printfParams->newlinePtr )
{
*printfParams->newlinePtr = 0; // to do BEFORE call to printTimeStamp
if ( printfParams->timestamp ) print_timestamp(printfParams);
}
#if PRINTF_LITE_BUF_SIZE > 1
printfParams->buf[(printfParams->bufIdx)++] = c;
#else
printfParams->transmitBufCallBack(&c, 1);
#endif
if ( c == '\n' ) {
*printfParams->newlinePtr = 1;
}
}else{
#if PRINTF_LITE_BUF_SIZE > 1
printfParams->buf[(printfParams->bufIdx)++] = c;
#else
printfParams->transmitBufCallBack(&c, 1);
#endif
}
#else
{
#if PRINTF_LITE_BUF_SIZE > 1
printfParams->buf[(printfParams->bufIdx)++] = c;
#else
printfParams->transmitBufCallBack(&c, 1);
#endif
}
#endif
#if PRINTF_LITE_BUF_SIZE > 1
if ( printfParams->bufIdx == PRINTF_LITE_BUF_SIZE ) {
printfParams->transmitBufCallBack(printfParams->buf, printfParams->bufIdx);
printfParams->bufIdx = 0;
}
#endif
}
#if PRINTF_OUTPUT_FORMAT_UNICODE == 1 && PRINTF_UTF8_SUPPORT == 1
#define halfBase 0x0010000UL
#define halfMask 0x3FFUL
#define halfShift 10 /* used for shifting by 10 bits */
#define UNI_SUR_HIGH_START 0xD800u
#define UNI_SUR_LOW_START 0xDC00u
static void print_string(const unsigned char* s, PrintfParams* printfParams)
{
while ( *s ) {
char32_t c;
if (*s & 0x80) {
if (*(s+1) == 0) {
// Finished in the middle of an utf8 multibyte char
return;
}
if ((*(s+1) & 0xc0) != 0x80) {
s += 1;
continue;
}
if ((*s & 0xe0) == 0xe0) {
if (*(s+2) == 0) {
// Finished in the middle of an utf8 multibyte char
return;
}
if ((*(s+2) & 0xc0) != 0x80) {
s += 2;
continue;
}
if ((*s & 0xf0) == 0xf0) {
if (*(s+3) == 0) {
// Finished in the middle of an utf8 multibyte char
return;
}
if ((*s & 0xf8) != 0xf0 || (*(s+3) & 0xc0) != 0x80) {
s += 3;
continue;
}
/* 4-byte code */
c = (*s & 0x7) << 18;
c |= (*(s+1) & 0x3f) << 12;
c |= (*(s+2) & 0x3f) << 6;
c |= *(s+3) & 0x3f;
s += 4;
} else {
/* 3-byte code */
c = (*s & 0xf) << 12;
c |= (*(s+1) & 0x3f) << 6;
c |= *(s+2) & 0x3f;
s += 3;
}
} else {
/* 2-byte code */
c = (*s & 0x1f) << 6;
c |= *(s+1) & 0x3f;
s += 2;
}
} else {
/* 1-byte code */
c = *s;
s += 1;
}
#if __WCHAR_MAX__ > 0xFFFFu
print_char(c, printfParams);
#else
if ( c <= 0xFFFF) {
print_char((wchar_t)c, printfParams);
} else {
c -= halfBase;
print_char((wchar_t)((c >> halfShift) + UNI_SUR_HIGH_START), printfParams);
print_char((wchar_t)((c & halfMask) + UNI_SUR_LOW_START), printfParams);
}
#endif
}
}
#endif
static void print_string(const printf_char_type* s, PrintfParams* printfParams)
{
while ( *s ) print_char(*s++, printfParams);
}
#if defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
static void print_Fstring(const char* s, PrintfParams* printfParams)
{
PGM_P p_to_print = reinterpret_cast<PGM_P>(s);
unsigned char c_to_print = pgm_read_byte(p_to_print++);
while ( c_to_print != 0 ) {
print_char(c_to_print, printfParams);
c_to_print = pgm_read_byte(p_to_print++);
}
}
#endif
#if PRINTF_LITE_LONGLONGINT_SUPPORT == 1 && PRINTF_LITE_LONGINT_SUPPORT == 1
#define INT_BIGGEST_TYPE long long int
#else
#if PRINTF_LITE_LONGINT_SUPPORT == 1
#define INT_BIGGEST_TYPE long int
#else
#define INT_BIGGEST_TYPE int
#endif
#endif
/* Jief : I found this here : https://github.com/cjlano/tinyprintf/blob/master/tinyprintf.c. Thanks CJlano */
static void print_ulonglong(unsigned INT_BIGGEST_TYPE v, unsigned int base, PrintfParams* printfParams, int printfSign)
{
int n = 0;
unsigned INT_BIGGEST_TYPE d = 1;
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
int nbDigits = 1 + printfSign;
#endif
while (v / d >= base) {
d *= base;
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
nbDigits += 1;
#endif
}
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1 && PRINTF_LITE_PADCHAR_SUPPORT == 1
if ( printfSign && printfParams->pad_char != ' ' ) print_char('-', printfParams);
#endif
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
while ( printfParams->width_specifier > nbDigits ) {
#if PRINTF_LITE_PADCHAR_SUPPORT == 1
print_char(printfParams->pad_char, printfParams);
#else
print_char(' ', printfParams);
#endif
nbDigits += 1;
}
#endif
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1 && PRINTF_LITE_PADCHAR_SUPPORT == 1
if ( printfSign && printfParams->pad_char == ' ' ) print_char('-', printfParams);
#else
if ( printfSign ) print_char('-', printfParams);
#endif
while (d != 0) {
unsigned int dgt = (unsigned int)(v / d); // cast is safe as v/d < 10
v %= d;
d /= base;
#if PRINTF_LITE_XSPECIFIER_SUPPORT == 1
print_char( (char)(dgt + (dgt < 10 ? '0' : (printfParams->uppercase ? 'A' : 'a') - 10)), printfParams);
#else
print_char( (char)(dgt + '0'), printfParams);
#endif
n += 1;
}
}
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
#if defined(EFIAPI)
#error TODO
#elif defined(__APPLE__)
#include <mach/mach_time.h>
uint32_t getUptimeInMilliseconds()
{
static mach_timebase_info_data_t s_timebase_info;
kern_return_t result = mach_timebase_info(&s_timebase_info);
(void(result));
// assert(result == 0);
// multiply to get value in the nano seconds
double multiply = (double)s_timebase_info.numer / (double)s_timebase_info.denom;
// divide to get value in the seconds
multiply /= 1000;
return mach_absolute_time() * multiply;
}
#endif
#endif //PRINTF_LITE_TIMESTAMP_SUPPORT
static void print_longlong(INT_BIGGEST_TYPE v, int base, PrintfParams* printfParams)
{
if ( v >= 0 ) return print_ulonglong(v, base, printfParams, 0);
print_ulonglong(-v, base, printfParams, 1); // -v doesn't work for INT64_MIN
}
#define PRINTF_LITE_REENTRANT 1
#if PRINTF_LITE_REENTRANT == 1 && PRINTF_LITE_TIMESTAMP_SUPPORT == 1
void printf_with_callback(const char* format, transmitBufCallBackType transmitBufCallBack,
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
int* newline, int timestamp,
#endif // PRINTF_LITE_TIMESTAMP_SUPPORT
...);
#ifdef ARDUINO
void printf_with_callback(const __FlashStringHelper* format, transmitBufCallBackType transmitBufCallBack
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, int* newline, int timestamp,
#endif // PRINTF_LITE_TIMESTAMP_SUPPORT
...);
#endif // ARDUINO
#include <inttypes.h> // for PRIu32
#endif // PRINTF_LITE_REENTRANT
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
static void print_timestamp(PrintfParams* printfParams)
{
#ifdef USE_HAL_DRIVER
uint32_t ms = HAL_GetTick();
#endif
#ifdef ARDUINO
uint32_t ms = millis();
#endif
#ifdef NRF51
uint32_t p_ticks;
uint32_t error_code = app_timer_cnt_get(&p_ticks);
APP_ERROR_CHECK(error_code);
uint32_t ms = p_ticks * ( ( NRF_RTC1->PRESCALER + 1 ) * 1000 ) / APP_TIMER_CLOCK_FREQ;
#endif
#ifdef __APPLE__
uint32_t ms = getUptimeInMilliseconds();
#endif
uint32_t s = ms/1000;
uint32_t m = s/60;
uint32_t h = m/60;
m %= 60;
s %= 60;
ms %= 1000;
#if PRINTF_LITE_REENTRANT == 1
#ifdef ARDUINO
printf_with_callback(F("%03" PRIu32 ":%02" PRIu32 ":%02" PRIu32 ".%03" PRIu32 " - "), printfParams->transmitBufCallBack, NULL, 0, h, m, s, ms);
#else
printf_with_callback("%03" PRIu32 ":%02" PRIu32 ":%02" PRIu32 ".%03" PRIu32 " - ", printfParams->transmitBufCallBack, NULL, 0, h, m, s, ms);
#endif
#else
// non reentrant version take a bit more code size
#if PRINTF_LITE_PADCHAR_SUPPORT == 1
char pad_char = printfParams->pad_char;
printfParams->pad_char = '0';
#endif
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
int width_specifier = printfParams->width_specifier;
printfParams->width_specifier = 3;
#endif
print_longlong(h, 10, printfParams);
print_char(':', printfParams);
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->width_specifier = 2;
#endif
print_longlong(m, 10, printfParams);
print_char(':', printfParams);
print_longlong(s, 10, printfParams);
print_char('.', printfParams);
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->width_specifier = 3;
#endif
print_longlong(ms, 10, printfParams);
// version 1
// for (int i=0 ; i<3 ; i++) print_char('-', printfParams);
// version 2
// print_char(' ', printfParams);
// print_char('-', printfParams);
// print_char(' ', printfParams);
// version 3
// print_Fstring(PSTR(" - "), printfParams);
// version 4
print_string(" - ", printfParams); // this one seems to use less space in flash, but 4 bytes in memory, on my Arduino UNO
#if PRINTF_LITE_PADCHAR_SUPPORT == 1
printfParams->pad_char = pad_char;
#endif
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->width_specifier = width_specifier;
#endif
#endif
}
#endif
#if PRINTF_LITE_FLOAT_SUPPORT == 1
/* Jief : I found this in Arduino code */
/* According to snprintf(),
*
* nextafter((double)numeric_limits<long long>::max(), 0.0) ~= 9.22337e+18
*
* This slightly smaller value was picked semi-arbitrarily. */
#define LARGE_DOUBLE_TRESHOLD (9.1e18)
/* THIS FUNCTION SHOULDN'T BE USED IF YOU NEED ACCURATE RESULTS.
*
* This implementation is meant to be simple and not occupy too much
* code size. However, printing floating point values accurately is a
* subtle task, best left to a well-tested library function.
*
* See Steele and White 2003 for more details:
*
* http://kurtstephens.com/files/p372-steele.pdf
*/
static void print_double(double number, PrintfParams* printfParams)
{
// Hackish fail-fast behavior for large-magnitude doubles
if (number >= LARGE_DOUBLE_TRESHOLD || number <= -LARGE_DOUBLE_TRESHOLD) {
if (number < 0.0) {
print_char('-', printfParams);
}
#if PRINTF_OUTPUT_FORMAT_UNICODE == 1 && PRINTF_UTF8_SUPPORT == 0
print_string(L"<large double>", printfParams);
#else
print_string((unsigned char*)"<large double>", printfParams);
#endif
}
int negative = 0;
if (number < 0.0) {
negative = 1;
number = -number;
}
// Simplistic rounding strategy so that e.g. print(1.999, 2)
// prints as "2.00"
double rounding = 0.5;
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
for (uint8_t i = 0; i < printfParams->precision_specifier; i++) {
rounding /= 10.0;
}
#else
for (uint8_t i = 0; i < 6; i++) {
rounding /= 10.0;
}
#endif
number += rounding;
// Extract the integer part of the number and print it
unsigned INT_BIGGEST_TYPE int_part = (unsigned INT_BIGGEST_TYPE)number; // we're sure it's positive number here.
double remainder = number - (double)int_part;
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
int width_specifier = printfParams->width_specifier;
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
printfParams->width_specifier -= printfParams->precision_specifier + (printfParams->precision_specifier ? 1 : 0); // doesn't matter if width_specifier is negative.
#else
printfParams->width_specifier -= 7; // doesn't matter if width_specifier is negative.
#endif
#endif
print_ulonglong(int_part, 10, printfParams, negative);
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->width_specifier = width_specifier;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
// Print the decimal point, but only if there are digits beyond
if (printfParams->precision_specifier > 0) {
print_char('.', printfParams);
}
#else
// if no precision support, it's always 6, so always a decimal point.
print_char('.', printfParams);
#endif
// Extract digits from the remainder one at a time
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
while (printfParams->precision_specifier-- > 0) {
#else
for ( int i=0 ; i<6 ; i++) {
#endif
remainder *= 10.0;
int to_print = (int)remainder;
print_char((char)(to_print + '0'), printfParams);
remainder -= to_print;
}
}
#endif
#ifdef __APPLE__
#define VALIST_PARAM_TYPE va_list
#define VALIST_PARAM(valist) valist
#define VALIST_ACCESS(valist) valist
#else
#define VALIST_PARAM_TYPE va_list*
#define VALIST_PARAM(valist) &valist
#define VALIST_ACCESS(valist) (*valist)
#endif
static void printf_handle_format_char(char c, VALIST_PARAM_TYPE valist, PrintfParams* printfParams)
{
if ( printfParams->inDirective )
{
switch(c)
{
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FIELDWIDTH_SUPPORT == 1 || PRINTF_LITE_FIELDPRECISION_SUPPORT == 1 || PRINTF_LITE_PADCHAR_SUPPORT == 1
case '0':
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
if ( printfParams->inWidthField ) {
printfParams->width_specifier *= 10;
}else
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
if ( printfParams->inPrecisionField ) {
printfParams->precision_specifier *= 10;
}
else
#endif
#if PRINTF_LITE_PADCHAR_SUPPORT == 1
printfParams->pad_char = '0';
#else
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 0
printfParams->inDirective = 0;
#endif
#endif
break;
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1 || (PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 && PRINTF_LITE_FIELDWIDTH_SUPPORT == 1)
if ( printfParams->inPrecisionField )
{
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1 // just ignore if we don't support precision field
printfParams->precision_specifier *= 10;
printfParams->precision_specifier += ( c - '0');
#endif
}
else
#endif
{
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->inWidthField = 1;
printfParams->width_specifier *= 10;
printfParams->width_specifier += ( c - '0');
#else
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1
// We just have to ignore field width
#else
// It's considered a mistake. Get out directive. Nothing will be printed. Harder to debug the format string for the user, but save sapce.
printfParams->inDirective = 0;
#endif
#endif
}
break;
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
case '.':
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->inWidthField = 0;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1 || (PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 && PRINTF_LITE_FIELDWIDTH_SUPPORT == 1)
printfParams->inPrecisionField = 1;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
printfParams->precision_specifier = 0;
#endif
break;
#endif
#endif // PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FIELDWIDTH_SUPPORT == 1 || PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
case 'z':
#if PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
printfParams->z_modifier = 1;
#else
printfParams->l_modifier = 2;
#endif
break;
#endif // PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_XSPECIFIER_SUPPORT == 1
case 'x':
case 'X':
#if PRINTF_LITE_XSPECIFIER_SUPPORT == 1
printfParams->uppercase = c == 'X';
#if PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
if ( printfParams->z_modifier ) print_ulonglong(va_arg(VALIST_ACCESS(valist), size_t), 16, printfParams, 0);
else
#endif
#if PRINTF_LITE_LONGLONGINT_SUPPORT == 1 && PRINTF_LITE_LONGINT_SUPPORT == 1
if ( printfParams->l_modifier == 2 ) print_ulonglong(va_arg(VALIST_ACCESS(valist), unsigned long long int), 16, printfParams, 0);
else
#endif
#if PRINTF_LITE_LONGINT_SUPPORT == 1
if ( printfParams->l_modifier != 0 ) print_ulonglong(va_arg(VALIST_ACCESS(valist), unsigned long int), 16, printfParams, 0);
else
#endif
print_ulonglong(va_arg(VALIST_ACCESS(valist), unsigned int), 16, printfParams, 0);
printfParams->inDirective = 0;
break;
#endif
#endif // PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_XSPECIFIER_SUPPORT == 1
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_USPECIFIER_SUPPORT == 1
case 'u':
#if PRINTF_LITE_USPECIFIER_SUPPORT == 1
#if PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
if ( printfParams->z_modifier ) print_ulonglong(va_arg(VALIST_ACCESS(valist), size_t), 10, printfParams, 0);
else
#endif
#if PRINTF_LITE_LONGLONGINT_SUPPORT == 1 && PRINTF_LITE_LONGINT_SUPPORT == 1
if ( printfParams->l_modifier == 2 ) print_ulonglong(va_arg(VALIST_ACCESS(valist), unsigned long long int), 10, printfParams, 0);
else
#endif // PRINTF_LITE_LONGLONGINT_SUPPORT == 1 && PRINTF_LITE_LONGINT_SUPPORT == 1
#if PRINTF_LITE_LONGINT_SUPPORT == 1
if ( printfParams->l_modifier != 0 ) print_ulonglong(va_arg(VALIST_ACCESS(valist), unsigned long int), 10, printfParams, 0);
else
#endif // PRINTF_LITE_LONGINT_SUPPORT == 1
print_ulonglong(va_arg(VALIST_ACCESS(valist), unsigned int), 10, printfParams, 0);
printfParams->inDirective = 0;
break;
#endif // PRINTF_LITE_USPECIFIER_SUPPORT
#endif // PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_USPECIFIER_SUPPORT == 1
case 'd':
#if PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
if ( printfParams->z_modifier ) print_longlong(va_arg(VALIST_ACCESS(valist), size_t), 10, printfParams); // we are using longlong version for every int to save code size.
else
#endif
#if PRINTF_LITE_LONGLONGINT_SUPPORT == 1 && PRINTF_LITE_LONGINT_SUPPORT == 1
if ( printfParams->l_modifier == 2 ) print_longlong(va_arg(VALIST_ACCESS(valist), long long int), 10, printfParams); // we are using longlong version for every int to save code size.
else
#endif
#if PRINTF_LITE_LONGINT_SUPPORT == 1
if ( printfParams->l_modifier != 0 ) print_longlong(va_arg(VALIST_ACCESS(valist), long int), 10, printfParams); // we are using longlong version for every int to save code size.
else
#endif
print_longlong(va_arg(VALIST_ACCESS(valist), int), 10, printfParams);
printfParams->inDirective = 0;
break;
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FLOAT_SUPPORT == 1
case 'f':
#if PRINTF_LITE_FLOAT_SUPPORT == 1
print_double(va_arg(VALIST_ACCESS(valist), double), printfParams); // 'float' is promoted to 'double' when passed through '...'
#elif PRINTF_LITE_FLOAT_AS_INT_SUPPORT == 1
print_longlong((INT_BIGGEST_TYPE)va_arg(VALIST_ACCESS(valist), double), 10, printfParams); // Cost 144 byte on Arduino
#else
va_arg(VALIST_ACCESS(valist), double); // this cost 16 bytes on stm32, 8 bytes on Arduino
#endif
printfParams->inDirective = 0;
break;
#endif // PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FLOAT_SUPPORT == 1
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_LONGINT_SUPPORT == 1 || PRINTF_LITE_FLOAT_SUPPORT == 1
case 'l':
#if PRINTF_LITE_LONGINT_SUPPORT == 1
printfParams->l_modifier += 1;
#endif
break;
#endif
case 'c':
#if PRINTF_OUTPUT_FORMAT_UNICODE == 1 && PRINTF_UTF8_SUPPORT == 1
if ( printfParams->l_modifier == 0 ) {
int c1 = (char)va_arg(VALIST_ACCESS(valist), int);
print_char((char)c1, printfParams); // 'char' is promoted to 'int' when passed through '...'
printfParams->inDirective = 0;
}else
#endif
{
// wchar_t tmp2 = L'a';
// int tmp1 = va_arg(VALIST_ACCESS(valist), int);
// int tmp3 = va_arg(VALIST_ACCESS(valist), wchar_t);
print_char((printf_char_type)va_arg(VALIST_ACCESS(valist), int), printfParams); // 'char' is promoted to 'int' when passed through '...'
printfParams->inDirective = 0;
}
break;
//#ifdef ARDUINO
//#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FLASHSTRING_SUPPORT == 1
// case 'F':
// #if PRINTF_LITE_FLASHSTRING_SUPPORT == 1
// print_Fstring(va_arg(VALIST_ACCESS(valist), char *), printfParams);
// #endif
// printfParams->inDirective = 0;
// break;
//#endif //PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FLASHSTRING_SUPPORT == 1
//#else //ARDUINO
//#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FLASHSTRING_SUPPORT == 0
// case 'F':
//#endif
//#endif
#if PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 || PRINTF_LITE_FLASHSTRING_SUPPORT == 1
case 'F':
#endif
#if defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
print_Fstring(va_arg(VALIST_ACCESS(valist), char *), printfParams);
printfParams->inDirective = 0;
break;
#endif //defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
case 's':
#if PRINTF_OUTPUT_FORMAT_UNICODE == 1
#endif
#if PRINTF_OUTPUT_FORMAT_UNICODE == 1 && PRINTF_UTF8_SUPPORT == 1
if ( printfParams->l_modifier == 0 ) {
print_string(va_arg(VALIST_ACCESS(valist), unsigned char *), printfParams);
printfParams->inDirective = 0;
}else
#endif
{
print_string(va_arg(VALIST_ACCESS(valist), printf_char_type *), printfParams);
printfParams->inDirective = 0;
}
break;
default: {
print_char('%', printfParams);
if ( c != '%' ) print_char(c, printfParams);
printfParams->inDirective = 0;
}
}
}
else
{
if ( c == '%' )
{
printfParams->inDirective = 1;
printfParams->l_modifier = 0;
#if PRINTF_LITE_ZSPECIFIER_SUPPORT == 1
printfParams->z_modifier = 0;
#endif
#if PRINTF_LITE_FIELDWIDTH_SUPPORT == 1
printfParams->inWidthField = 0;
printfParams->width_specifier = 0;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1 || (PRINTF_LITE_FALLBACK_FOR_UNSUPPORTED == 1 && PRINTF_LITE_FIELDWIDTH_SUPPORT == 1)
printfParams->inPrecisionField = 0;
#endif
#if PRINTF_LITE_FIELDPRECISION_SUPPORT == 1
printfParams->precision_specifier = 6; // 6 digits for float, as specified by ANSI, if I remeber well
#endif
#if PRINTF_LITE_PADCHAR_SUPPORT == 1
printfParams->pad_char = ' ';
#endif
}
else
{
print_char(c, printfParams);
}
}
}
void vprintf_with_callback(const char* format, va_list valist, transmitBufCallBackType transmitBufCallBack
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, int* newline, int timestamp
#endif
)
{
PrintfParams printfParams;
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
printfParams.newlinePtr = newline;
printfParams.timestamp = timestamp;
#endif
#if PRINTF_LITE_BUF_SIZE > 1
printfParams.bufIdx = 0;
#endif
printfParams.inDirective = 0;
printfParams.transmitBufCallBack = transmitBufCallBack;
while ( 1 ) //Iterate over formatting string
{
char c = *format++;
if (c == 0) break;
printf_handle_format_char(c, VALIST_PARAM(valist), &printfParams);
}
#if PRINTF_LITE_BUF_SIZE > 1
if ( printfParams.bufIdx > 0 ) printfParams.transmitBufCallBack(printfParams.buf, printfParams.bufIdx);
#endif
va_end(valist);
}
void printf_with_callback(const char* format, transmitBufCallBackType transmitBufCallBack,
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
int* newline, int timestamp,
#endif
...)
{
va_list valist;
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
va_start(valist, timestamp);
#else
va_start(valist, transmitBufCallBack);
#endif
vprintf_with_callback(format, valist,transmitBufCallBack
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, NULL, 0
#endif
);
va_end(valist);
}
#if defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
void vprintf_with_callback(const __FlashStringHelper *format, va_list valist, transmitBufCallBackType transmitBufCallBack
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, int* newline, int timestamp
#endif
)
{
PrintfParams printfParams;
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
printfParams.newlinePtr = newline;
printfParams.timestamp = timestamp;
#endif
#if PRINTF_LITE_BUF_SIZE > 1
printfParams.bufIdx = 0;
#endif
printfParams.inDirective = 0;
printfParams.transmitBufCallBack = transmitBufCallBack;
PGM_P p = reinterpret_cast<PGM_P>(format);
while (1)
{
char c = pgm_read_byte(p++);
if (c == 0) break;
printf_handle_format_char(c, &valist, &printfParams);
}
#if PRINTF_LITE_BUF_SIZE > 1
if ( printfParams.bufIdx > 0 ) printfParams.transmitBufCallBack(printfParams.buf, printfParams.bufIdx);
#endif
va_end(valist);
}
void printf_with_callback(const __FlashStringHelper* format, transmitBufCallBackType transmitBufCallBack,
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
int* newline, int timestamp,
#endif
...)
{
va_list valist;
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
va_start(valist, timestamp);
#else
va_start(valist, transmitBufCallBack);
#endif
vprintf_with_callback(format, valist, transmitBufCallBack
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, NULL, 0
#endif
);
va_end(valist);
}
#endif // defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
/* ------------------------ SPRINTF ------------------------ */
#if PRINTF_LITE_SNPRINTF_SUPPORT == 1
printf_char_type* sprintfBuf;
size_t sprintfBufLen;
void transmitSprintf(const printf_char_type* buf, size_t nbyte)
{
size_t i=0;
for ( ; sprintfBufLen>0 && i<nbyte ; i++) {
*sprintfBuf++ = buf[i];
sprintfBufLen--;
}
}
int vsnprintf(printf_char_type* buf, size_t len, const char *__restrict format, va_list valist)
{
sprintfBuf = buf;
sprintfBufLen = len-1;
vprintf_with_callback(format, valist, transmitSprintf
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, NULL, 0
#endif
);
*sprintfBuf = 0;
return 1;
}
int snprintf(printf_char_type*, size_t len, const char *__restrict format, ...)
{
va_list valist;
va_start(valist, format);
vsnprintf(buf, len, format, valist);
va_end(valist);
return 1;
}
#if defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
int vsnprintf(char *__restrict buf, size_t len, const __FlashStringHelper *__restrict format, va_list valist)
{
sprintfBuf = buf;
sprintfBufLen = len-1;
vprintf_with_callback(format, valist, transmitSprintf
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, NULL, 0
#endif
);
*sprintfBuf = 0;
return 1;
}
int snprintf(char *__restrict buf, size_t len, const __FlashStringHelper *__restrict format, ...)
{
va_list valist;
va_start(valist, format);
vsnprintf(buf, len, format, valist);
va_end(valist);
return 1;
}
#endif // defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
#endif // PRINTF_LITE_SNPRINTF_SUPPORT
#if PRINTF_LITE_USB_SUPPORT == 1
#ifdef __USBD_CDC_IF_H
/* ------------------------ USB ------------------------ */
void transmitBufUsb(const char* buf, size_t nbyte)
{
#ifdef DEBUG
#if PRINTF_LITE_BUF_SIZE == 0
if ( nbyte > 1 ) {
__asm volatile ("bkpt 0");
}
#else
if ( nbyte > PRINTF_LITE_BUF_SIZE ) {
__asm volatile ("bkpt 0");
}
#endif
#endif
// uint32_t ms = HAL_GetTick() + 3000;
// while ( HAL_GetTick() < ms && CDC_Transmit_FS((char*)buf, nbyte) == USBD_BUSY ) {}; // If data isn't consumed by the host in 1 ms, it probaly won't be so we give up to not block.
uint32_t t0 = HAL_GetTick();
uint8_t ret = CDC_Transmit_FS((uint8_t*)buf, (uint16_t)nbyte); // nbbyte is < BUF_MAX so it's safe to assume we can cast it to uint16_t.
if ( ret != USBD_OK )
{
uint32_t now = HAL_GetTick();
while ( now - t0 < 300 && ret != USBD_OK ) { // What to do if can't send ? With uart, there no flow control so char can get lost.
ret = CDC_Transmit_FS((uint8_t*)buf, (uint16_t)nbyte);
now = HAL_GetTick();
}
}
}
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
static int usb_newline = 1;
#endif
void printf_usb(const char* format, ...)
{
va_list valist;
va_start(valist, format);
vprintf_with_callback(format, valist, transmitBufUsb
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &usb_newline, 0
#endif
);
va_end(valist);
}
void vlogf_usb(const char* format, va_list valist)
{
vprintf_with_callback(format, valist, transmitBufUsb
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &usb_newline, 1
#endif
);
}
void logf_usb(const char* format, ...)
{
va_list valist;
va_start(valist, format);
vlogf_usb(format, valist);
va_end(valist);
}
#endif
#endif // PRINTF_LITE_USB_SUPPORT
/* ------------------------ SERIAL ------------------------ */
#if PRINTF_LITE_UART_SUPPORT == 1
#ifdef __STM32F1xx_HAL_UART_H // STM32
static void transmitBufUart(const char* buf, size_t nbyte)
{
int ret = HAL_UART_Transmit(&huart1, (uint8_t*)buf, (uint16_t)nbyte, 1000); // nbbyte is < BUF_MAX so it's safe to assume we can cast it to uint16_t.
if ( ret != HAL_OK ) // this is only to be able to put a breakpoint in case the first HAL_UART_Transmit return !HAL_OK
{
while ( ret != HAL_OK )
{
ssize_t nbByteNotTransmitted = huart1.TxXferCount + (ret == HAL_TIMEOUT ? 1 : 0); // size to transmit.
if ( nbByteNotTransmitted <= 0 ) {
#ifdef DEBUG
__asm volatile ("bkpt 0");
#endif
}
buf += nbyte - nbByteNotTransmitted;
nbyte = nbByteNotTransmitted;
ret = HAL_UART_Transmit(&huart1, (uint8_t*)buf, (uint16_t)nbyte, 1000);
}
}
}
#endif
#ifdef ARDUINO
static void transmitBufUart(const char* buf, size_t nbyte)
{
for (size_t i=0 ; i<nbyte ; i++) {
Serial.write(buf[i]);
}
}
#endif
#ifdef NRF51
static void transmitBufUart(const char* buf, size_t nbyte)
{
for (size_t i=0 ; i<nbyte ; i++) {
do {} while ( app_uart_put(buf[i]) != NRF_SUCCESS);
}
}
#endif
#ifdef __APPLE__
// so far, this is just for testing and debugging. It sends all to console.
#include <stdio.h>
static void transmitBufUart(const char* buf, size_t nbyte)
{
for (size_t i=0 ; i<nbyte ; i++) {
putchar(buf[i]);
}
}
#endif
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
static int uart_newline = 1; // newline is static avoid being reinitialized at each call
#endif
void vprintf_uart(const char* format, va_list valist)
{
vprintf_with_callback(format, valist, transmitBufUart
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &uart_newline, 0
#endif
);
}
void printf_uart(const char* format, ...)
{
va_list valist;
va_start(valist, format);
vprintf_uart(format, valist);
va_end(valist);
}
void vlogf_uart(const char* format, va_list valist)
{
vprintf_with_callback(format, valist, transmitBufUart
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &uart_newline, 1
#endif
);
}
void logf_uart(const char* format, ...)
{
va_list valist;
va_start(valist, format);
vlogf_uart(format, valist);
va_end(valist);
}
#if defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
void vprintf_uart(const __FlashStringHelper* format, va_list valist)
{
vprintf_with_callback(format, valist, transmitBufUart
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &uart_newline, false
#endif
);
}
void printf_uart(const __FlashStringHelper *format, ...)
{
va_list valist;
va_start(valist, format);
vprintf_uart(format, valist);
va_end(valist);
}
void vlogf_uart(const __FlashStringHelper* format, va_list valist)
{
vprintf_with_callback(format, valist, transmitBufUart
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &uart_newline, true
#endif
);
}
void logf_uart(const __FlashStringHelper *format, ...)
{
va_list valist;
va_start(valist, format);
vlogf_uart(format, valist);
va_end(valist);
}
#endif // defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
#endif // PRINTF_LITE_UART_SUPPORT
/* ------------------------ TRACE ------------------------ */
#if defined(OS_USE_TRACE_ITM) || defined(OS_USE_TRACE_SEMIHOSTING_DEBUG) || defined(OS_USE_TRACE_SEMIHOSTING_STDOUT)
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
static int newlinePtr = 1;
#endif
void my_trace_write(const char* buf ,size_t nbyte)
{
trace_write(buf, nbyte);
}
void vprintf_semih(const char* format, va_list valist)
{
vprintf_with_callback(format, valist, my_trace_write
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &newlinePtr, 1
#endif
);
// // TODO: rewrite it to no longer use newlib, it is way too heavy
// // Print to the local buffer
// ret = vsnprintf(buf, sizeof(buf), format, ap);
// if (ret > 0) {
// // Transfer the buffer to the device
// ret = trace_write(buf, (size_t) ret);
// }
//
}
void printf_semih(const char* format, ...)
{
int ret;
va_list ap;
va_start(ap, format);
vprintf_semih(format, ap);
va_end(ap);
}
#endif
/* ---------------------- LCD --------------------------- */
#ifdef LiquidCrystal_h
extern LiquidCrystal lcd;
static int lcd_newline = 1; // newline is static avoid being reinitialized at each call
static void transmitBufLcd(const char* buf, size_t nbyte)
{
// lcd.write(buf, nbyte);
for (size_t i=0 ; i<nbyte ; i++) {
lcd.write(buf[i]);
}
}
void printf_lcd(int row, int col, const char *format, ...)
{
lcd.setCursor(col, row);
va_list valist;
va_start(valist, format);
vprintf_with_callback(format, valist, transmitBufLcd
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &lcd_newline, 0
#endif
);
va_end(valist);
}
#if defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
void printf_lcd(int row, int col, const __FlashStringHelper *format, ...)
{
lcd.setCursor(col, row);
va_list valist;
va_start(valist, format);
vprintf_with_callback(format, valist, transmitBufLcd
#if PRINTF_LITE_TIMESTAMP_SUPPORT == 1
, &lcd_newline, 0
#endif
);
va_end(valist);
}
#endif // defined(ARDUINO) && PRINTF_LITE_FLASHSTRING_SUPPORT == 1
#endif