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18F87J50

 
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gokhangokcen



Joined: 30 Oct 2015
Posts: 4
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18F87J50
PostPosted: Mon May 21, 2018 4:46 am     Reply with quote

Hello, i want to ethernet project with 18F87j50 and enc28j60. but compiler not compile.

I build 18f4620 and enc28j60 and working but not compile 18f87j50.

What is my problem? please help me. I don't have adcon2?




>>> Warning 215 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\StackTsk2.h" Line 135(5,19): Undefined identifier STACK_USE_WIFI
>>> Warning 215 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\StackTsk2.h" Line 174(5,19): Undefined identifier STACK_USE_WIFI
>>> Warning 215 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\StackTsk2.h" Line 190(5,19): Undefined identifier STACK_USE_WIFI
>>> Warning 237 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\main.h" Line 46(44,45): Extra comma
>>> Warning 209 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\StackTsk.c" Line 338(1,1): Assignment to enum is not of the correct type
*** Error 12 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\Helpers.c" Line 235(17,23): Undefined identifier ADCON2
*** Error 12 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\Helpers.c" Line 247(4,10): Undefined identifier ADCON2
*** Error 56 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\Helpers.c" Line 264(18,20): Element is not a member
*** Error 56 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\Helpers.c" Line 266(24,26): Element is not a member
*** Error 12 "C:\Program Files (x86)\PICC\Projelerim\Deneme1\tcpip\Helpers.c" Line 300(4,10): Undefined identifier ADCON2
5 Errors, 5 Warnings.
Build Failed.
temtronic



Joined: 01 Jul 2010
Posts: 9243
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PostPosted: Mon May 21, 2018 6:30 am     Reply with quote

OK, I do not use either of those PICs, but you should download the datasheets for them and compare what is different between them.
Also look at the 'device.header' files that CCS supplies( the first line in any program) to see what is available. It seems ADCON2 is not available.

You've made several changes from the original 'working' program as there are several errors not just the 'no ADCON2 error'.
I know reading 500-600 pages of datasheets isn't fun, but focus on the ADC chapters...assuming ADCON2 means the ADC control register #2.

Jay
Ttelmah



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PostPosted: Mon May 21, 2018 7:36 am     Reply with quote

The 87J50 doesn't have an ADCON2 register.
What is the code trying to access the register directly?.

ADCON2 programs the acquisition time and data justification. This is done by different bits in ADCON1 on the 87J50.

The code that talks to the ADC needs to be re-written....

The CCS functions automatically switch to the different registers. You have 'hand coded' routines to directly access the registers, and these need to change for the different chip.
gokhangokcen



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PostPosted: Mon May 21, 2018 9:06 am     Reply with quote

yes, i'm search datasheet and code. and edit helpers.c file.
now working code.

i'm share helpers.c file. it might work for someone else.

re-edit code
Code:

/*********************************************************************
 
 Helper Functions for Microchip TCPIP Stack
 
 FileName:      Helpers.c
 Dependencies:  See INCLUDES section
 Processor:     PIC18, PIC24, dsPIC, PIC32
 Compiler:      Microchip C18, C30, C32
 Company:       Microchip Technology, Inc.

 Software License Agreement

 Copyright (C) 2002-2011 Microchip Technology Inc.  All rights
 reserved.

 Microchip licenses to you the right to use, modify, copy, and
 distribute:
 (i)  the Software when embedded on a Microchip microcontroller or
      digital signal controller product ("Device") which is
      integrated into Licensee's product; or
 (ii) ONLY the Software driver source files ENC28J60.c, ENC28J60.h,
      ENCX24J600.c and ENCX24J600.h ported to a non-Microchip device
      used in conjunction with a Microchip ethernet controller for
      the sole purpose of interfacing with the ethernet controller.

 You should refer to the license agreement accompanying this
 Software for additional information regarding your rights and
 obligations.

 THE SOFTWARE AND DOCUMENTATION ARE PROVIDED "AS IS" WITHOUT
 WARRANTY OF ANY KIND, EITHER EXPRESS OR IMPLIED, INCLUDING WITHOUT
 LIMITATION, ANY WARRANTY OF MERCHANTABILITY, FITNESS FOR A
 PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT SHALL
 MICROCHIP BE LIABLE FOR ANY INCIDENTAL, SPECIAL, INDIRECT OR
 CONSEQUENTIAL DAMAGES, LOST PROFITS OR LOST DATA, COST OF
 PROCUREMENT OF SUBSTITUTE GOODS, TECHNOLOGY OR SERVICES, ANY CLAIMS
 BY THIRD PARTIES (INCLUDING BUT NOT LIMITED TO ANY DEFENSE
 THEREOF), ANY CLAIMS FOR INDEMNITY OR CONTRIBUTION, OR OTHER
 SIMILAR COSTS, WHETHER ASSERTED ON THE BASIS OF CONTRACT, TORT
 (INCLUDING NEGLIGENCE), BREACH OF WARRANTY, OR OTHERWISE.

 ********************************************************************
 File Description:
 
 Change History:
 
  Rev         Description
  ----------  -------------------------------------------------------
  1.0 - 5.31  Initial release; Rewritten CalcIPChecksum() to avoid
              multi-byte shift operation; Added hexatob(),
              btohexa_high(), and btohexa_low(); Optimized swapl();
              Added leftRotateDWORD()
  5.36        Updated compile time check for ultoa();

   DARREN ROOK/CCS   Remove leftRotateDWORD()

 ********************************************************************/
#define __HELPERS_C

#include <stdarg.h>
#include "TCPIP Stack/TCPIP.h"


// Default Random Number Generator seed. 0x41FE9F9E corresponds to calling LFSRSeedRand(1)
static DWORD dwLFSRRandSeed = 0x41FE9F9E;

/*****************************************************************************
  Function:
   DWORD LFSRSeedRand(DWORD dwSeed)

  Summary:
   Seeds the LFSR random number generator invoked by the LFSRRand() function. 
   The prior seed is returned.

  Description:
   Seeds the LFSR random number generator invoked by the LFSRRand() function. 
   The prior seed is returned.

  Precondition:
   None

  Parameters:
   wSeed - The new 32-bit seed value to assign to the LFSR.

  Returns:
     The last seed in use.  This can be saved and restored by a subsequent call
   to LFSRSeedRand() if you wish to use LFSRRand() in multiple contexts
   without disrupting the random number sequence from the alternative
   context.  For example, if App 1 needs a given sequence of random numbers
   to perform a test, if you save and restore the seed in App 2, it is
   possible for App 2 to not disrupt the random number sequence provided to
   App 1, even if the number of times App 2 calls LFSRRand() varies.
     
  Side Effects:
   None
   
  Remarks:
   Upon initial power up, the internal seed is initialized to 0x1.  Using a
   dwSeed value of 0x0 will return the same sequence of random numbers as
   using the seed of 0x1.
  ***************************************************************************/
DWORD LFSRSeedRand(DWORD dwSeed)
{
   DWORD dwOldSeed;
   BYTE i;

   // Save original seed to be returned later
   dwOldSeed = dwLFSRRandSeed;

   // Ensure zero isn't selected as a seed value, this would result in all
   // 0x0000 output values from the LFSR
   if(dwSeed == 0u)
      dwSeed = 1;
     
   // Set the new seed
   dwLFSRRandSeed = dwSeed;
   
   // Run the LFSR a few times to get rid of obvious start up artifacts for
   // seed values that don't have many set bits.
   for(i = 0; i < 16; i++)
      LFSRRand();
   
   // Return saved old seed
   return dwOldSeed;
}

/*****************************************************************************
  Function:
   WORD LFSRRand(void)

  Summary:
   Returns a pseudo-random 16-bit unsigned integer in the range from 0
   to 65535 (0x0000 to 0xFFFF).

  Description:
   Returns a pseudo-random 16-bit unsigned integer in the range from 0
   to 65535 (0x0000 to 0xFFFF).  The random number is generated using a
   Linear Feedback Shift Register (LFSR) type pseudo-random number generator
   algorithm.  The LFSR can be seeded by calling the LFSRSeedRand() function
   to generate the same sequence of random numbers as a prior string of calls.
   
   The internal LFSR will repeat after 2^32-1 iterations.

  Precondition:
   None

  Parameters:
   None

  Returns:
     Random 16-bit unsigned integer.
     
  Side Effects:
   The internal LFSR seed is updated so that the next call to LFSRRand()
   will return a different random number.
   
  Remarks:
   None
  ***************************************************************************/
WORD LFSRRand(void)
{
   BYTE i;
   
   // Taps: 32 31 29 1
   // Characteristic polynomial: x^32 + x^31 + x^29 + x + 1
   // Repeat 15 times to make the shift pattern less obvious
   for(i = 0; i < 15; i++)
      dwLFSRRandSeed = (dwLFSRRandSeed >> 1) ^ ((0ul - (dwLFSRRandSeed & 1ul)) & 0xD0000001ul);

   // Return 16-bits as pseudo-random number
   return (WORD)dwLFSRRandSeed;
}


/*****************************************************************************
  Function:
   DWORD GenerateRandomDWORD(void)

  Summary:
   Generates a random DWORD.

  Description:
   This function generates a random 32-bit integer.  It collects
   randomness by comparing the A/D converter's internal R/C oscillator
   clock with our main system clock.  By passing collected entropy to the
   LFSRSeedRand()/LFSRRand() functions, the output is normalized (deskewed)
   in the hopes of meeting statistical randomness tests.

  Precondition:
   None

  Parameters:
   None

  Returns:
     Random 32-bit number.
     
  Side Effects:
   This function uses the A/D converter (and so you must disable
   interrupts if you use the A/D converted in your ISR).  The LFSRRand()
   function will be reseeded, and Timer0 (PIC18) and Timer1 (PIC24,
   dsPIC, and PIC32) will be used.  TMR#H:TMR#L will have a new value.
   Note that this is the same timer used by the Tick module.
   
  Remarks:
   This function times out after 1 second of attempting to generate the
   random DWORD.  In such a case, the output may not be truly random. 
   Typically, this function executes in around 500,000 instruction cycles.
   
   The intent of this function is to produce statistically random and
   cryptographically secure random number.  Whether or not this is true on
   all (or any) devices/voltages/temperatures is not tested.
  ***************************************************************************/
DWORD GenerateRandomDWORD(void)
{
   BYTE vBitCount;
   WORD w, wTime, wLastValue;
   DWORD dwTotalTime;
   union
   {
      DWORD   dw;
      WORD   w[2];
   } randomResult;

#if defined __18CXX   
{
   BYTE ADCON0Save, ADCON2Save;
   BYTE T0CONSave, TMR0HSave, TMR0LSave;
   #if getenv("SFR_VALID:T0CON1")
   BYTE T0CONSave1;
   #endif

   // Save hardware SFRs
   ADCON0Save = ADCON0;
   ADCON2Save = ADCON1;
   #if getenv("SFR_VALID:T0CON1")
   T0CONSave = T0CON0;
   T0CONSave1 = T0CON1;
   #else
   T0CONSave = T0CON;
   #endif
   TMR0LSave = TMR0L;
   TMR0HSave = TMR0H;

   // Set up Timer and A/D converter module
   ADCON0 = 0x01;   // Turn on the A/D module
   ADCON1 = 0x3F;   // 20 Tad acquisition, Frc A/D clock used for conversion
   #if getenv("SFR_VALID:T0CON1")
   T0CON0 = 0;
   T0CON1 = 0x40;
   T0CON0 = 0x90;
   #else
   T0CON = 0x88;   // TMR0ON = 1, no prescalar, 16bit
   #endif
   vBitCount = 0;
   dwTotalTime = 0;
   wLastValue = 0;
   randomResult.dw = LFSRRand();
   
   for(;;)
   {
      // Time the duration of an A/D acquisition and conversion
      TMR0H = 0x00;
      TMR0L = 0x00;
      //ADCON0bits.GO = 1;
      ANCON1bits.GO = 1;
      ClrWdt();
      while(ANCON1bits.GO);
      ((BYTE*)&wTime)[0] = TMR0L;
      ((BYTE*)&wTime)[1] = TMR0H;     
     
      w = LFSRRand();
   
      // Wait no longer than 1 second obtaining entropy
      dwTotalTime += wTime;
      if(dwTotalTime >= GetInstructionClock())
      {
         randomResult.w[0] ^= LFSRRand();
         randomResult.w[1] ^= LFSRRand();
         break;
      }
   
     
      // Keep sampling if minimal entropy was likely obtained this round
      if(wLastValue == wTime)
         continue;
   
      // Add this entropy into the pseudo random number generator by reseeding
      LFSRSeedRand(w + (wLastValue - wTime));
      wLastValue = wTime;
   
      // Accumulate at least 32 bits of randomness over time
      randomResult.dw <<= 1;
      if(LFSRRand() & 0x0080)
         randomResult.w[0] |= 0x1;
   
      // See if we've collected a fair amount of entropy and can quit early
      if(++vBitCount == 0u)
         break;
   }


   // Restore hardware SFRs
   ADCON0 = ADCON0Save;
   ADCON1 = ADCON2Save;
   TMR0H = TMR0HSave;
   TMR0L = TMR0LSave;
   #if getenv("SFR_VALID:T0CON1")
   T0CON0 = 0;
   T0CON1 = T0CONSave1;
   T0CON0 = T0CONSave;
   #else
   T0CON = T0CONSave;
   #endif   
}
#else
{

   WORD AD1CON1Save, AD1CON2Save, AD1CON3Save;
   WORD T1CONSave, PR1Save;

   // Save hardware SFRs
   AD1CON1Save = AD1CON1;
   AD1CON2Save = AD1CON2;
   AD1CON3Save = AD1CON3;
   T1CONSave = T1CON;
   PR1Save = PR1;
   


   // Set up Timer and A/D converter module
   AD1CON1 = 0x0000;      // Turn off the ADC so we can write to it
   AD1CON3 = 0x9F00;      // Frc A/D clock, 31 Tad acquisition
   AD1CON2 = 0x003F;      // Interrupt after every 16th sample/convert
   AD1CON1 = 0x80E4;      // Turn on the A/D module, auto-convert
   T1CON = 0x8000;         // TON = 1, no prescalar
   PR1 = 0xFFFF;         // Don't clear timer early
   vBitCount = 0;
   dwTotalTime = 0;
   wLastValue = 0;
   randomResult.dw = LFSRRand();
   for(;;)
   {
      ClrWdt();
      #if defined(__C30__)
         while(!IFS0bits.AD1IF);
      #else
         while(!IFS1bits.AD1IF);
      #endif
      wTime = TMR1;
      TMR1 = 0x0000;

      #if defined(__C30__)
         IFS0bits.AD1IF = 0;
      #else
         IFS1CLR = _IFS1_AD1IF_MASK;
      #endif
      w = LFSRRand();
   
      // Wait no longer than 1 second obtaining entropy
      dwTotalTime += wTime;
      if(dwTotalTime >= GetInstructionClock())
      {
         randomResult.w[0] ^= LFSRRand();
         randomResult.w[1] ^= LFSRRand();
         break;
      }
   
      // Keep sampling if minimal entropy was likely obtained this round
      if(wLastValue == wTime)
         continue;
   
      // Add this entropy into the pseudo random number generator by reseeding
      LFSRSeedRand(w + (wLastValue - wTime));
      wLastValue = wTime;
   
      // Accumulate at least 32 bits of randomness over time
      randomResult.dw <<= 1;
      if(LFSRRand() & 0x0080)
         randomResult.w[0] |= 0x1;
   
      // See if we've collected a fair amount of entropy and can quit early
      if(++vBitCount == 0u)
         break;
   }


   // Restore hardware SFRs
   AD1CON1 = 0x0000;      // Turn off the ADC so we can write to it
   AD1CON3 = AD1CON3Save;
   AD1CON2 = AD1CON2Save;
   AD1CON1 = AD1CON1Save;
   T1CON = T1CONSave;
   PR1 = PR1Save;
}
#endif

   return randomResult.dw;
}


#if defined(STACK_USE_HTTP_SERVER)
/*****************************************************************************
  Function:
   void UnencodeURL(BYTE* URL)

  Summary:
   Decodes a URL-encoded string.

  Description:
   This function is deprecated except for use with HTTP Classic.  It
   attempts to decode a URL encoded string, converting all hex escape
   sequences into a literal byte.  However, it is inefficient over long
   strings and does not handle URL-encoded data strings ('&' and '=').

  Precondition:
   None

  Parameters:
   URL - the null-terminated string to decode

  Returns:
     None
  ***************************************************************************/
void UnencodeURL(BYTE* URL)
{
   BYTE *Right, *Copy;
   WORD_VAL Number;

   while((Right = (BYTE*)strchr((char*)URL, '%')))
   {
      // Make sure the string is long enough
      if(Right[1] == '\0')
         break;
      if(Right[2] == '\0')
         break;

      // Update the string in place
      Number.v[0] = Right[2];
      Number.v[1] = Right[1];
      *Right++ = hexatob(Number);
      URL = Right;

      // Remove two blank spots by shifting all remaining characters right two
      Copy = Right + 2;
      while((*Right++ = *Copy++));
   }
}         
#endif


/*****************************************************************************
  Function:
   BOOL StringToIPAddress(BYTE* str, IP_ADDR* IPAddress)

  Summary:
   Converts a string to an IP address

  Description:
   This function parses a dotted-quad decimal IP address string into an
   IP_ADDR struct.  The output result is big-endian.
   
  Precondition:
   None

  Parameters:
   str - Pointer to a dotted-quad IP address string
   IPAddress - Pointer to IP_ADDR in which to store the result

  Return Values:
     TRUE - an IP address was successfully decoded
     FALSE - no IP address could be found, or the format was incorrect
  ***************************************************************************/
BOOL StringToIPAddress(BYTE* str, IP_ADDR* IPAddress)
{
   DWORD_VAL dwVal;
   BYTE i, charLen, currentOctet;

   charLen = 0;
   currentOctet = 0;
   dwVal.Val = 0;
   
   //while((i = *str++))   //ccs removed
   for(;;)  //ccs added
   {
      i = *str++; //ccs added this and next line
      if (!i) break;

      if(currentOctet > 3u)
         break;

      i -= '0';
     

      // Validate the character is a numerical digit or dot, depending on location
      if(charLen == 0u)
      {
         if(i > 9u)
            return FALSE;
      }
      else if(charLen == 3u)
      {
         if(i != (BYTE)('.' - '0'))
            return FALSE;

         if(dwVal.Val > 0x00020505ul)
            return FALSE;

         IPAddress->v[currentOctet++] = dwVal.v[2]*((BYTE)100) + dwVal.v[1]*((BYTE)10) + dwVal.v[0];
         charLen = 0;
         dwVal.Val = 0;
         continue;
      }
      else
      {
         if(i == (BYTE)('.' - '0'))
         {
            if(dwVal.Val > 0x00020505ul)
               return FALSE;

            IPAddress->v[currentOctet++] = dwVal.v[2]*((BYTE)100) + dwVal.v[1]*((BYTE)10) + dwVal.v[0];
            charLen = 0;
            dwVal.Val = 0;
            continue;
         }
         if(i > 9u)
            return FALSE;
      }

      charLen++;
      dwVal.Val <<= 8;
      dwVal.v[0] = i;
   }

   // Make sure the very last character is a valid termination character
   // (i.e., not more hostname, which could be legal and not an IP
   // address as in "10.5.13.233.picsaregood.com"
   if(i != 0u && i != '/' && i != '\r' && i != '\n' && i != ' ' && i != '\t' && i != ':')
      return FALSE;

   // Verify and convert the last octet and return the result
   if(dwVal.Val > 0x00020505ul)
      return FALSE;

   IPAddress->v[3] = dwVal.v[2]*((BYTE)100) + dwVal.v[1]*((BYTE)10) + dwVal.v[0];

   return TRUE;
}

/*****************************************************************************
  Function:
   BOOL ROMStringToIPAddress(ROM BYTE* str, IP_ADDR* IPAddress)

  Summary:
   Converts a string to an IP address

  Description:
   This function parses a dotted-quad decimal IP address string into an
   IP_ADDR struct.  The output result is big-endian.
   
  Precondition:
   None

  Parameters:
   str - Pointer to a dotted-quad IP address string
   IPAddress - Pointer to IP_ADDR in which to store the result

  Return Values:
     TRUE - an IP address was successfully decoded
     FALSE - no IP address could be found, or the format was incorrect
 
  Remarks:
   This function is aliased to StringToIPAddress on non-PIC18 platforms.
  ***************************************************************************/
#if defined(__18CXX)
BOOL ROMStringToIPAddress(ROM BYTE* str, IP_ADDR* IPAddress)
{
   DWORD_VAL dwVal;
   BYTE i, charLen, currentOctet;

   charLen = 0;
   currentOctet = 0;
   dwVal.Val = 0;

   //while(i = *str++)  //ccs removed
   for (;;) //ccs added
   {
      i = *str++; //ccs added this and next line
      if (!i)  break;
     
      if(currentOctet > 3u)
         break;

      i -= '0';
     

      // Validate the character is a numerical digit or dot, depending on location
      if(charLen == 0u)
      {
         if(i > 9u)
            return FALSE;
      }
      else if(charLen == 3u)
      {
         if(i != (BYTE)('.' - '0'))
            return FALSE;

         if(dwVal.Val > 0x00020505ul)
            return FALSE;

         IPAddress->v[currentOctet++] = dwVal.v[2]*((BYTE)100) + dwVal.v[1]*((BYTE)10) + dwVal.v[0];
         charLen = 0;
         dwVal.Val = 0;
         continue;
      }
      else
      {
         if(i == (BYTE)('.' - '0'))
         {
            if(dwVal.Val > 0x00020505ul)
               return FALSE;

            IPAddress->v[currentOctet++] = dwVal.v[2]*((BYTE)100) + dwVal.v[1]*((BYTE)10) + dwVal.v[0];
            charLen = 0;
            dwVal.Val = 0;
            continue;
         }
         if(i > 9u)
            return FALSE;
      }

      charLen++;
      dwVal.Val <<= 8;
      dwVal.v[0] = i;
   }

   // Make sure the very last character is a valid termination character
   // (i.e., not more hostname, which could be legal and not an IP
   // address as in "10.5.13.233.picsaregood.com"
   if(i != 0u && i != '/' && i != '\r' && i != '\n' && i != ' ' && i != '\t')
      return FALSE;

   // Verify and convert the last octet and return the result
   if(dwVal.Val > 0x00020505ul)
      return FALSE;

   IPAddress->v[3] = dwVal.v[2]*((BYTE)100) + dwVal.v[1]*((BYTE)10) + dwVal.v[0];

   return TRUE;
}
#endif



/*****************************************************************************
  Function:
   WORD Base64Decode(BYTE* cSourceData, WORD wSourceLen,
                  BYTE* cDestData, WORD wDestLen)

  Description:
   Decodes a Base-64 array to its literal representation.
   
  Precondition:
   None

  Parameters:
   cSourceData - Pointer to a string of Base-64 encoded data
   wSourceLen   - Length of the Base-64 source data
   cDestData   - Pointer to write the decoded data
   wSourceLen   - Maximum length that can be written to cDestData

  Returns:
     Number of decoded bytes written to cDestData.
 
  Remarks:
   This function is binary safe and will ignore invalid characters (CR, LF,
   etc).  If cSourceData is equal to cDestData, the data will be converted
   in-place.  If cSourceData is not equal to cDestData, but the regions
   overlap, the behavior is undefined.
   
   Decoded data is always at least 1/4 smaller than the source data.
  ***************************************************************************/
#if defined(STACK_USE_BASE64_DECODE)
WORD Base64Decode(BYTE* cSourceData, WORD wSourceLen, BYTE* cDestData, WORD wDestLen)
{
   BYTE i;
   BYTE vByteNumber;
   WORD wBytesOutput;

   vByteNumber = 0;
   wBytesOutput = 0;

   // Loop over all provided bytes
   while(wSourceLen--)
   {
      // Fetch a Base64 byte and decode it to the original 6 bits
      i = *cSourceData++;
      if(i >= 'A' && i <= 'Z')   // Regular data
         i -= 'A' - 0;
      else if(i >= 'a' && i <= 'z')
         i -= 'a' - 26;
      else if(i >= '0' && i <= '9')
         i -= '0' - 52;
      else if(i == '+' || i == '-')
         i = 62;
      else if(i == '/' || i == '_')
         i = 63;
      else                   // Skip all padding (=) and non-Base64 characters
         continue;


      // Write the 6 bits to the correct destination location(s)
      if(vByteNumber == 0u)
      {
         vByteNumber++;
         if(wBytesOutput >= wDestLen)
            break;
         wBytesOutput++;
         *cDestData = i << 2;
      }
      else if(vByteNumber == 1u)
      {
         vByteNumber++;
         *cDestData++ |= i >> 4;
         if(wBytesOutput >= wDestLen)
            break;
         wBytesOutput++;
         *cDestData = i << 4;
      }
      else if(vByteNumber == 2u)
      {
         vByteNumber++;
         *cDestData++ |= i >> 2;
         if(wBytesOutput >= wDestLen)
            break;
         wBytesOutput++;
         *cDestData = i << 6;
      }
      else
      {
         vByteNumber = 0;
         *cDestData++ |= i;
      }
   }

   return wBytesOutput;
}
#endif   // #if defined(STACK_USE_BASE64_DECODE)


/*****************************************************************************
  Function:
   WORD Base64Encode(BYTE* cSourceData, WORD wSourceLen,
                  BYTE* cDestData, WORD wDestLen)

  Description:
   Encodes a binary array to Base-64.
   
  Precondition:
   None

  Parameters:
   cSourceData - Pointer to a string of binary data
   wSourceLen   - Length of the binary source data
   cDestData   - Pointer to write the Base-64 encoded data
   wSourceLen   - Maximum length that can be written to cDestData

  Returns:
     Number of encoded bytes written to cDestData.  This will always be
     a multiple of 4.
 
  Remarks:
   Encoding cannot be performed in-place.  If cSourceData overlaps with
   cDestData, the behavior is undefined.
   
   Encoded data is always at least 1/3 larger than the source data.  It may
   be 1 or 2 bytes larger than that.
  ***************************************************************************/
#if defined(STACK_USE_BASE64_ENCODE) || defined(STACK_USE_SMTP_CLIENT) || defined(STACK_USE_DYNAMICDNS_CLIENT)
WORD Base64Encode(BYTE* cSourceData, WORD wSourceLen, BYTE* cDestData, WORD wDestLen)
{
   BYTE i, j;
   BYTE vOutput[4];
   WORD wOutputLen;

   wOutputLen = 0;
   while(wDestLen >= 4u)
   {
      // Start out treating the output as all padding
      vOutput[0] = 0xFF;
      vOutput[1] = 0xFF;
      vOutput[2] = 0xFF;
      vOutput[3] = 0xFF;

      // Get 3 input octets and split them into 4 output hextets (6-bits each)
      if(wSourceLen == 0u)
         break;
      i = *cSourceData++;
      wSourceLen--;
      vOutput[0] = (i & 0xFC)>>2;
      vOutput[1] = (i & 0x03)<<4;
      if(wSourceLen)
      {
         i = *cSourceData++;
         wSourceLen--;
         vOutput[1] |= (i & 0xF0)>>4;
         vOutput[2] = (i & 0x0F)<<2;
         if(wSourceLen)
         {
            i = *cSourceData++;
            wSourceLen--;
            vOutput[2] |= (i & 0xC0)>>6;
            vOutput[3] = i & 0x3F;
         }
      }
   
      // Convert hextets into Base 64 alphabet and store result
      for(i = 0; i < 4u; i++)
      {
         j = vOutput[i];

         if(j <= 25u)
            j += 'A' - 0;
         else if(j <= 51u)
            j += 'a' - 26;
         else if(j <= 61u)
            j += '0' - 52;
         else if(j == 62u)
            j = '+';
         else if(j == 63u)
            j = '/';
         else            // Padding
            j = '=';

         *cDestData++ = j;
      }

      // Update counters
      wDestLen -= 4;
      wOutputLen += 4;
   }

   return wOutputLen;
}
#endif // #if defined(STACK_USE_BASE64_ENCODE) || defined(STACK_USE_SMTP) || defined(STACK_USE_DYNAMICDNS_CLIENT)


/*****************************************************************************
  Function:
   void uitoa(WORD Value, BYTE* Buffer)

  Summary:
   Converts an unsigned integer to a decimal string.
   
  Description:
   Converts a 16-bit unsigned integer to a null-terminated decimal string.
   
  Precondition:
   None

  Parameters:
   Value   - The number to be converted
   Buffer   - Pointer in which to store the converted string

  Returns:
     None
  ***************************************************************************/
void uitoa(WORD Value, BYTE* Buffer)
{
   BYTE i;
   WORD Digit;
   WORD Divisor;
   BOOL Printed = FALSE;

   if(Value)
   {
      for(i = 0, Divisor = 10000; i < 5u; i++)
      {
         Digit = Value/Divisor;
         if(Digit || Printed)
         {
            *Buffer++ = '0' + Digit;
            Value -= Digit*Divisor;
            Printed = TRUE;
         }
         Divisor /= 10;
      }
   }
   else
   {
      *Buffer++ = '0';
   }

   *Buffer = '\0';
}             

/*****************************************************************************
  Function:
   void ultoa(DWORD Value, BYTE* Buffer)

  Summary:
   Converts an unsigned integer to a decimal string.
   
  Description:
   Converts a 32-bit unsigned integer to a null-terminated decimal string.
   
  Precondition:
   None

  Parameters:
   Value   - The number to be converted
   Buffer   - Pointer in which to store the converted string

  Returns:
     None
  ***************************************************************************/
// HI-TECH PICC-18 PRO 9.63, C30 v3.25, and C32 v1.12 already have a ultoa() library function
// C18 already has a ultoa() function that more-or-less matches this one
// C32 < 1.12 and C30 < v3.25 need this function
#if (defined(__PIC32MX__) && (__C32_VERSION__ < 112)) || (defined (__C30__) && (__C30_VERSION__ < 325)) || defined(__C30_LEGACY_LIBC__) || defined(__C32_LEGACY_LIBC__)
void ultoa(DWORD Value, BYTE* Buffer)
{
   BYTE i;
   DWORD Digit;
   DWORD Divisor;
   BOOL Printed = FALSE;

   if(Value)
   {
      for(i = 0, Divisor = 1000000000; i < 10; i++)
      {
         Digit = Value/Divisor;
         if(Digit || Printed)
         {
            *Buffer++ = '0' + Digit;
            Value -= Digit*Divisor;
            Printed = TRUE;
         }
         Divisor /= 10;
      }
   }
   else
   {
      *Buffer++ = '0';
   }

   *Buffer = '\0';
}
#endif

/*****************************************************************************
  Function:
   BYTE hexatob(WORD_VAL AsciiChars)

  Summary:
   Converts a hex string to a single byte.
   
  Description:
   Converts a two-character ASCII hex string to a single packed byte.
   
  Precondition:
   None

  Parameters:
   AsciiChars - WORD_VAL where .v[0] is the ASCII value for the lower nibble
               and .v[1] is the ASCII value for the upper nibble.  Each
               must range from '0'-'9', 'A'-'F', or 'a'-'f'.

  Returns:
     Resulting packed byte 0x00 - 0xFF.
  ***************************************************************************/
BYTE hexatob(WORD_VAL AsciiChars)
{
   // Convert lowercase to uppercase
   if(AsciiChars.v[1] > 'F')
      AsciiChars.v[1] -= 'a'-'A';
   if(AsciiChars.v[0] > 'F')
      AsciiChars.v[0] -= 'a'-'A';

   // Convert 0-9, A-F to 0x0-0xF
   if(AsciiChars.v[1] > '9')
      AsciiChars.v[1] -= 'A' - 10;
   else
      AsciiChars.v[1] -= '0';

   if(AsciiChars.v[0] > '9')
      AsciiChars.v[0] -= 'A' - 10;
   else
      AsciiChars.v[0] -= '0';

   // Concatenate
   return (AsciiChars.v[1]<<4) |  AsciiChars.v[0];
}

/*****************************************************************************
  Function:
   BYTE btohexa_high(BYTE b)

  Summary:
   Converts the upper nibble of a binary value to a hexadecimal ASCII byte.

  Description:
   Converts the upper nibble of a binary value to a hexadecimal ASCII byte.
   For example, btohexa_high(0xAE) will return 'A'.

  Precondition:
   None

  Parameters:
   b - the byte to convert

  Returns:
     The upper hexadecimal ASCII byte '0'-'9' or 'A'-'F'.
  ***************************************************************************/
BYTE btohexa_high(BYTE b)
{
   b >>= 4;
   return (b>0x9u) ? b+'A'-10:b+'0';
}

/*****************************************************************************
  Function:
   BYTE btohexa_high(BYTE b)

  Summary:
   Converts the lower nibble of a binary value to a hexadecimal ASCII byte.

  Description:
   Converts the lower nibble of a binary value to a hexadecimal ASCII byte.
   For example, btohexa_high(0xAE) will return 'E'.

  Precondition:
   None

  Parameters:
   b - the byte to convert

  Returns:
     The lower hexadecimal ASCII byte '0'-'9' or 'A'-'F'.
  ***************************************************************************/
BYTE btohexa_low(BYTE b)
{
   b &= 0x0F;
   return (b>9u) ? b+'A'-10:b+'0';
}

/*****************************************************************************
  Function:
   signed char stricmppgm2ram(BYTE* a, ROM BYTE* b)

  Summary:
   Case-insensitive comparison of a string in RAM to a string in ROM.

  Description:
   Performs a case-insensitive comparison of a string in RAM to a string
   in ROM.  This function performs identically to strcmppgm2ram, except that
   the comparison is not case-sensitive.

  Precondition:
   None

  Parameters:
   a - Pinter to tring in RAM
   b - Pointer to string in ROM

  Return Values:
     \-1 - a < b
     0   - a = b
     1   - a > b
  ***************************************************************************/
//signed char stricmppgm2ram(BYTE* a, ROM BYTE* b)
signed char stricmppgm2ram(char* a, ROM char* b)   //__CCS__ __PCH__ __PCD__
{
   char cA, cB;
   
   // Load first two characters
   cA = *a;
   cB = *b;

   //debug_http2(debug_putc, "stricmppgm2ram() '%s' '%s' %x.%x ", a, b, cA, cB);
 
   // Loop until one string terminates
   while(cA != '\0' && cB != '\0')
   {
      // Shift case if necessary
      if(cA >= 'a' && cA <= 'z')
         cA -= 'a' - 'A';
      if(cB >= 'a' && cB <= 'z')
         cB -= 'a' - 'A';
         
      // Compare
      if(cA > cB)
      {
         //debug_http2(debug_putc, ">\r\n");
         return 1;
      }
      if(cA < cB)
      {
         //debug_http2(debug_putc, "<\r\n");
         return -1;
      }
     
      // Characters matched, so continue
      a++;
      b++;
      cA = *a;
      cB = *b;
     
      //debug_http2(debug_putc, "%x.%x ", cA, cB);     
   }
   
   // See if one string terminated first
   if(cA > cB)
   {
      //debug_http2(debug_putc, "done >\r\n");
      return 1;
   }
   if(cA < cB)
   {
      //debug_http2(debug_putc, "done <\r\n");
      return -1;
   }

   //debug_http2(debug_putc, "done =\r\n");

   // Strings match
   return 0;
}

/*****************************************************************************
  Function:
   WORD swaps(WORD v)

  Description:
   Swaps the endian-ness of a WORD.

  Precondition:
   None

  Parameters:
   v - the WORD to swap

  Returns:
   The swapped version of v.
  ***************************************************************************/
WORD swaps(WORD v)
{
   WORD_VAL t;
   BYTE b;

   t.Val   = v;
   b       = t.v[1];
   t.v[1]  = t.v[0];
   t.v[0]  = b;

   return t.Val;
}

/*****************************************************************************
  Function:
   DWORD swapl(DWORD v)

  Description:
   Swaps the endian-ness of a DWORD.

  Precondition:
   None

  Parameters:
   v - the DWORD to swap

  Returns:
   The swapped version of v.
  ***************************************************************************/
#if defined(__C32__)
DWORD   __attribute__((nomips16)) swapl(DWORD v)
#else
DWORD swapl(DWORD v)
#endif
{
   // Swap bytes 0 and 3
   ((DWORD_VAL*)&v)->v[0] ^= ((DWORD_VAL*)&v)->v[3];
   ((DWORD_VAL*)&v)->v[3] ^= ((DWORD_VAL*)&v)->v[0];
   ((DWORD_VAL*)&v)->v[0] ^= ((DWORD_VAL*)&v)->v[3];

   // Swap bytes 1 and 2
   ((DWORD_VAL*)&v)->v[1] ^= ((DWORD_VAL*)&v)->v[2];
   ((DWORD_VAL*)&v)->v[2] ^= ((DWORD_VAL*)&v)->v[1];
   ((DWORD_VAL*)&v)->v[1] ^= ((DWORD_VAL*)&v)->v[2];

   return v;
}


/*****************************************************************************
  Function:
   WORD CalcIPChecksum(BYTE* buffer, WORD count)

  Summary:
   Calculates an IP checksum value.

  Description:
   This function calculates an IP checksum over an array of input data.  The
   checksum is the 16-bit one's complement of one's complement sum of all
   words in the data (with zero-padding if an odd number of bytes are
   summed).  This checksum is defined in RFC 793.

  Precondition:
   buffer is WORD aligned (even memory address) on 16- and 32-bit PICs.

  Parameters:
   buffer - pointer to the data to be checksummed
   count  - number of bytes to be checksummed

  Returns:
   The calculated checksum.
   
  Internal:
   This function could be improved to do 32-bit sums on PIC32 platforms.
  ***************************************************************************/
WORD CalcIPChecksum(BYTE* buffer, WORD count)
{
   WORD i;
   WORD *val;
   union
   {
      WORD w[2];
      DWORD dw;
   } sum;

   i = count >> 1;
   val = (WORD*)buffer;

   // Calculate the sum of all words
   sum.dw = 0x00000000ul;
   while(i--)
      sum.dw += (DWORD)*val++;

   // Add in the sum of the remaining byte, if present
   if(count & 0x1)
      sum.dw += (DWORD)*(BYTE*)val;

   // Do an end-around carry (one's complement arrithmatic)
   sum.dw = (DWORD)sum.w[0] + (DWORD)sum.w[1];

   // Do another end-around carry in case if the prior add
   // caused a carry out
   sum.w[0] += sum.w[1];

   // Return the resulting checksum
   return ~sum.w[0];
}


/*****************************************************************************
  Function:
   char* strupr(char* s)

  Summary:
   Converts a string to uppercase.

  Description:
   This function converts strings to uppercase on platforms that do not
   already have this function defined.  All lower-case characters are
   converted, an characters not included in 'a'-'z' are left as-is.

  Precondition:
   None

  Parameters:
   s - the null-terminated string to be converted.

  Returns:
   Pointer to the initial string.
  ***************************************************************************/
#if (!defined(__CCS__) && !defined(__18CXX)) || defined(HI_TECH_C)
char* strupr(char* s)
{
   char c;
   char *t;

   t = s;
   while( (c = *t) )
   {
      if(c >= 'a' && c <= 'z')
      {
         *t -= ('a' - 'A');
      }
      t++;
   }
   return s;
}
#endif

#if 0 //ccs disabled
#if defined(__18CXX) //&& !defined(__PCH__)
// Make this variable global for the following function.
// Hi-Tech PICC18 cannot access local function variables from inline asm.
DWORD_VAL toRotate;
#endif
#endif

/*****************************************************************************
  Function:
   DWORD leftRotateDWORD(DWORD val, BYTE bits)

  Summary:
   Left-rotates a DWORD.

  Description:
   This function rotates the bits in a 32-bit DWORD left by a specific
   number of bits.

  Precondition:
   None

  Parameters:
   val      - the DWORD to be rotated
   bits   - the number of bits by which to shift

  Returns:
   Rotated DWORD value.
   
  Remarks:
   This function is only implemented on 8-bit platforms for now.  The
   8-bit compilers generate excessive code for this function, while C30
   and C32 already generate compact code.  Those compilers are served
   by a macro defined in Helpers.h.
  ***************************************************************************/
#if defined(__18CXX) && !defined(__PCH__)
DWORD leftRotateDWORD(DWORD val, BYTE bits)
{
   BYTE i, t;
   DWORD_VAL toRotate;  //ccs un-commented
   toRotate.Val = val;
   
   for(i = bits; i >= 8u; i -= 8)
   {
      t = toRotate.v[3];
      toRotate.v[3] = toRotate.v[2];
      toRotate.v[2] = toRotate.v[1];
      toRotate.v[1] = toRotate.v[0];
      toRotate.v[0] = t;
   }
   
   
   #if defined(HI_TECH_C)
   for(; i != 0; i--)
   {
      asm("movlb (_toRotate)>>8");
      //asm("bcf _STATUS,0,C");
      asm("bcf 0xFD8,0,C");      // HI-TECH PICC-18 PRO 9.63PL1 doesn't define _STATUS
      asm("btfsc (_toRotate)&0ffh+3,7,B");
      //asm("bsf _STATUS,0,C");
      asm("bsf 0xFD8,0,C");      // HI-TECH PICC-18 PRO 9.63PL1 doesn't define _STATUS
      asm("rlcf (_toRotate)&0ffh+0,F,B");
      asm("rlcf (_toRotate)&0ffh+1,F,B");
      asm("rlcf (_toRotate)&0ffh+2,F,B");
      asm("rlcf (_toRotate)&0ffh+3,F,B");
   }
   #else
   for(; i != 0u; i--)
   {
      _asm
      movlb toRotate
      bcf STATUS,0,0
      btfsc toRotate+3,7,1
      bsf STATUS,0,0
      rlcf toRotate+0,1,1
      rlcf toRotate+1,1,1
      rlcf toRotate+2,1,1
      rlcf toRotate+3,1,1
      _endasm
   }
   #endif
   
   return toRotate.Val;
}
#endif

/*****************************************************************************
  Function:
   void FormatNetBIOSName(BYTE Name[])

  Summary:
   Formats a string to a valid NetBIOS name.

  Description:
   This function formats a string to a valid NetBIOS name.  Names will be
   exactly 16 characters, as defined by the NetBIOS spec.  The 16th
   character will be a 0x00 byte, while the other 15 will be the
   provided string, padded with spaces as necessary.

  Precondition:
   None

  Parameters:
   Name - the string to format as a NetBIOS name.  This parameter must have
     at least 16 bytes allocated.

  Returns:
   None
  ***************************************************************************/
void FormatNetBIOSName(BYTE Name[])
{
   BYTE i;

   Name[15] = '\0';
   strupr((char*)Name);
   i = 0;
   while(i < 15u)
   {
      if(Name[i] == '\0')
      {
         while(i < 15u)
         {
            Name[i++] = ' ';
         }
         break;
      }
      i++;
   }
}

/*****************************************************************************
  Function:
   char * strnchr(const char *searchString, size_t count, char c)

  Summary:
   Searches a string up to a specified number of characters for a specific
   character.

  Description:
   Searches a string up to a specified number of characters for a specific
   character.  The string is searched forward and the first occurance
   location is returned.  If the search character is not present in the
   string, or if the maximum character count is reached first, then a NULL
   pointer is returned.

  Precondition:
   None

  Parameters:
   searchString - Pointer to a null terminated string to search.  If count is
      less than the string size, then the string need not be null terminated.
   count - Maximum number of characters to search before aborting.
   c - Character to search for
   
  Returns:
   Pointer to the first occurance of the character c in the string
   searchString.  If the character is not found or the maximum count is
   reached, a NULL pointer is returned.
  ***************************************************************************/
char * strnchr(const char *searchString, size_t count, char c)
{
   char c2;
   
   while(count--)
   {
      c2  = *searchString++;
      if(c2 == 0u)
         return NULL;
      if(c2 == c)
         return (char*)--searchString;
   }
   return NULL;
}


/*****************************************************************************
  Function:
   char* strncpy_m(char* destStr, size_t destSize, int nStrings, ...)

  Summary:
   Copies multiple strings to a destination

  Description:
   Copies multiple strings to a destination
    but doesn't copy more than destSize characters.
    Useful where the destination is actually an array and an extra \0
    won't be appended to overflow the buffer
   
  Precondition:
   - valid string pointers
    - destSize should be > 0

  Parameters:
   destStr - Pointer to a string to be initialized with the multiple strings provided as arguments.

    destSize    - the maximum size of the destStr field, that cannot be exceeded.
                  An \0 won't be appended if the resulting size is > destSize

    nStrings    - number of string parameters to be copied into destStr

    ...         - variable number of arguments
   
   
  Returns:
   Length of the destination string, terminating \0 (if exists) not included
  ***************************************************************************/
size_t strncpy_m(char* destStr, size_t destSize, int nStrings, ...)
{
    va_list     args;
    const char* str;
    char*       end;
    size_t      len;

    destStr[0] = '\0';
    end = destStr + destSize - 1;
    *end = '\0';
    len = 0;
   
    va_start( args, nStrings );
   
    while(nStrings--)
    {
        if(*end)
        {   // if already full don't calculate strlen outside the string area
            len = destSize;
            break;
        }
       
        str = va_arg(args, const char*);
        strncpy(destStr + len, str, destSize - len);
        len += strlen(str);
    }

    va_end( args );
   
    return len;
}


/*****************************************************************************
  Function:
   BYTE ExtractURLFields(BYTE *vURL,
                    PROTOCOLS *protocol,
                    BYTE *vUsername, WORD *wUsernameLen,
                    BYTE *vPassword, WORD *wPasswordLen,
                    BYTE *vHostname, WORD *wHostnameLen,
                    WORD *wPort,
                    BYTE *vFilePath, WORD *wFilePathLen)

  Summary:
   Extracts all parameters from an URL string (ex:
   "http://admin:[email protected]:8080/myfile.gif" is split into
   {PROTOCOL_HTTP, "admin", "passwd", "www.microchip.com", 8080, "/myfile.gif"}.

  Description:
   Extracts all parameters from an URL string (ex:
   "http://admin:[email protected]:8080/myfile.gif" is split into
   {PROTOCOL_HTTP, "admin", "passwd", "www.microchip.com", 8080, "/myfile.gif"}.
   
   The URL string can be null terminated, or alternatively could be terminated
   by a carriage return or line feed.
   
   If the protocol is unrecognized or the protocol is recognized but the URL
   is malformed, than an error is safely returned.  For more information on
   URL/URI interpretation see RFC 2396.

  Precondition:
   This function is commented out by default to save code space because
   it is not used by any current stack features.  However, if you want to use
   it, go ahead and uncomment it.  It has been tested, so it (should) work
   correctly.

  Parameters:
   vURL -   Pointer to null terminated URL to decode and extract from.  This
      parameter is required and needs to have the minimum RFC 1738 components
      in it (protocol and hostname).
     
   protocol - Optional pointer to a PROTOCOLS enum to retrieve the decoded
      protocol type.  If this parameter is unneeded, specify a NULL pointer. 
      The protocol is a required part of the URL, so it must always be
      present.  The protocol also determines what scheme all other parameters
      are decoded using, so the function will fail if an unrecognized
      protocol is provided.  The PROTOCOLS enum members show all of the
      currently supported protocols for this function.
     
      <p>For the example URL provided in the function description,
      PROTOCOL_HTTP would be returned for this field.
     
   vUsername - Optional pointer to a buffer to write the decoded username
      portion of the URL.  If the URL does not contain a username or a NULL
      pointer is supplied, then this field is ignored.

      <p>For the example URL provided in the function description, "admin"
      would be returned for this field.
     
   wUsernameLen -
      On call\: Optional pointer to a WORD specifying the maximum length of
      the vUsername buffer, including the null terminator character.
     
      <p>Upon return\: If wUsernameLen and vUsername are non-NULL, the
      *wUsernameLen WORD is updated with the actual number of characters
      written to the vUsername buffer, including the null terminator
      character.  If vUsername is NULL but wUsernameLen is non-NULL, then no
      characters are copied, but *wUsernameLen will return the number of
      characters required to fit the full username string.  If wUsernameLen
      is NULL, then the username field in the URL, if present, is ignored and
      the vUsername pointer is not used.
     
      <p>If zero characters were written, this indicates that the URL did not
      contain a username field.  If one character was written, this indicates
      that a username field was present, but was a zero character string
      (ex\: "").
       
      <p>For the example URL provided in the function description, 6 (0x0006)
      would be returned for this field.
     
   vPassword - Optional pointer to a buffer to write the decoded password
      portion of the URL.  If the URL does not contain a password or a NULL
      pointer is supplied, then this field is ignored.

      <p>For the example URL provided in the function description, "passwd"
      would be returned for this field.
     
   wPasswordLen -
      On call\: Optional pointer to a WORD specifying the maximum length of
      the vPassword buffer, including the null terminator character.
     
      <p>Upon return\: If wPasswordLen and vPassword are non-NULL, the
      *wPasswordLen WORD is updated with the actual number of characters
      written to the vPassword buffer, including the null terminator
      character.  If vPassword is NULL but wPasswordLen is non-NULL, then no
      characters are copied, but *wPasswordLen will return the number of
      characters required to fit the full password string.  If wPasswordLen
      is NULL, then the password field in the URL, if present, is ignored and
      the vPassword pointer is not used.
     
      <p>If zero characters were written, this indicates that the URL did not
      contain a password field.  If one character was written, this indicates
      that a password field was present, but was a zero character string
      (ex\: "").
       
      <p>For the example URL provided in the function description, 7 (0x0007)
      would be returned for this field.
     
   vHostname - Optional pointer to a buffer to write the decoded hostname
      portion of the URL.  All Internet URLs must contain a hostname or IP
      address, however, if a NULL pointer is supplied, then this field is
      ignored.

      <p>For the example URL provided in the function description,
      "www.microchip.com" would be returned for this field.  If the URL was
      "http://192.168.0.1", then this field would be returned as
      "192.168.0.1".   The IP address would not be decoded to a DWORD (use the
      StringToIPAddress() helper function to do this).
     
   wHostnameLen -
      On call\: Optional pointer to a WORD specifying the maximum length of
      the vHostname buffer, including the null terminator character.
     
      <p>Upon return\: If wHostnameLen and vHostname are non-NULL, the
      *wHostnameLen WORD is updated with the actual number of characters
      written to the vHostname buffer, including the null terminator
      character.  If vHostname is NULL but wHostnameLen is non-NULL, then no
      characters are copied, but *wHostnameLen will return the number of
      characters required to fit the full hostname string.  If wHostnameLen
      is NULL, then the hostname field in the URL, is ignored and the
      vHostname pointer is not used.
     
      <p>For the example URL provided in the function description,
      18 (0x0012) would be returned for this field.  If the URL was
      "http://192.168.0.1", then this field would be returned as 12 (0x000C).
     
   wPort - Optional pointer to a WORD specifying the TCP or UDP port that the
      server is listening on.  If the port field is absent from the URL, then
      this parameter will specify the default port for the protocol.  For
      example, "http://www.microchip.com" would result in 80 being return as
      the specified port.
       
      <p>If the wPort pointer is NULL, then the port field in the URL
      is ignored, if present.
     
   vFilePath - Optional pointer to a buffer to write the decoded file path
      portion of the URL.  If a NULL pointer is supplied, then this field is
      ignored.  If a file path is not present in the URL, then "/" will be
      returned in this field. 

      <p>For the example URL provided in the function description,
      "/myfile.gif" would be returned for this field.
     
   wFilePathLen -
      On call\: Optional pointer to a WORD specifying the maximum length of
      the vFilePath buffer, including the null terminator character.
     
      <p>Upon return\: If wFilePathLen and vFilePath are non-NULL, the
      *wFilePathLen WORD is updated with the actual number of characters
      written to the vFilePath buffer, including the null terminator
      character.  If vFilePath is NULL but wFilePathLen is non-NULL, then no
      characters are copied, but *wFilePathLen will return the number of
      characters required to fit the full file path string.  If wFilePathLen
      is NULL, then the file path field in the URL, if present, is ignored and
      the vFilePath pointer is not used.
     
      <p>This function always returns "/" if no file path is present, so
      *wFilePathLen will also be at least 2 characters ('/' and null
      terminator) if the pointer is non-NULL.
   
      <p>For the example URL provided in the function description, 12 (0x000C)
      would be returned for this field.
     
  Returns:
   Zero on success.  Nonzero indicates an error code.  If a nonzero error code
   is returned, none of the returned buffers or pointer values should be
   treated as valid, but some of them may have been written to.  The following
   are all possible return values.
   <table>
      0   No error
      1   Protocol unknown (additional code needs to be added to
          ExtractURLFields() and the PROTOCOLS enum needs to be updated if
          you want to decode URLs of this protocol type.
      2   URL malformed. Illegal or unknown URL format encountered.
      3   Buffer too small.  One of the input buffer sizes is too small to
          contain the URL parameter.
   </table>
  ***************************************************************************/
#if 0   
BYTE ExtractURLFields(BYTE *vURL, PROTOCOLS *protocol, BYTE *vUsername, WORD *wUsernameLen, BYTE *vPassword, WORD *wPasswordLen, BYTE *vHostname, WORD *wHostnameLen, WORD *wPort, BYTE *vFilePath, WORD *wFilePathLen)
{
   // These two arrays must exactly match up each other and the PROTOCOLS enum
   // elements.  The protocol name strings must also be specified in all
   // lowercase.
   static ROM char * ROM   vProtocolNames[] = {"http", "https", "mms", "rtsp"};
   static ROM WORD       wProtocolPorts[] = { 80,     443,     1755,  554};
   WORD w, w2;
   BYTE i, j;
   PROTOCOLS prot;
   BYTE *temp, *temp2;
   WORD wURLLen;
   WORD wLocalPort;
   
   
   // Calculate how long this URL is
   wURLLen = strlen((char*)vURL);
   temp = (BYTE*)strnchr((char*)vURL, wURLLen, '\r');
   if(temp)
      wURLLen = temp - vURL;
   temp = (BYTE*)strnchr((char*)vURL, wURLLen, '\n');
   if(temp)
      wURLLen = temp - vURL;
   

   // Parse starting protocol field
   // Find out how long the protocol name field is
   temp = (BYTE*)strnchr((char*)vURL, wURLLen, ':');
   if(temp == NULL)
      return 2;
   
   // Search protocol list to see if this is a recognized protocol
   for(prot = 0; (BYTE)prot < sizeof(wProtocolPorts)/sizeof(wProtocolPorts[0]); prot++)
   {
      w = strlenpgm(vProtocolNames[prot]);
      if((WORD)(temp - vURL) == w)
      {
         w2 = 0;
         temp2 = vURL;
         while(w)
         {
            i = *temp2++;
            if((i >= 'A') && (i <= 'Z'))
               i += 'a' - 'A';
            if(i != (BYTE)vProtocolNames[prot][w2++])
               break;
            w--;
         }
         if(w == 0u)
         {
            if(protocol)
               *protocol = prot;
            break;
         }
      }
   }

   // If we've search the whole list and didn't find a match, then
   // this protocol is unknown and this URL cannot be parsed.
   if((BYTE)prot >= sizeof(wProtocolPorts)/sizeof(wProtocolPorts[0]))
      return 1;
   
   w = temp - vURL + 1;
   vURL += w;
   wURLLen -= w;

   // Protocols using the authority field all must have a double
   // slash "//" prefix
   if(wURLLen < 2u)
      return 2;
   for(j = 0; j < 2u; j++)
   {
      i = *vURL++;
      if(i != '/')
         return 2;
   }
   wURLLen -= 2;
   

   // Parse username and password fields
   // See if there is a @ sign, indicating that there is at
   // least a username and possibly a password in this URL
   temp = (BYTE*)strnchr((char*)vURL, wURLLen, '@');
   if(temp == NULL)
   {
      if(wUsernameLen)
         *wUsernameLen = 0;
      if(wPasswordLen)
         *wPasswordLen = 0;
   }
   else
   {
      // If we get down here, there is a user name present, let's
      // see if a password is also present by searching for a
      // colon between the current string position and the @
      // symbol.
      temp2 = (BYTE*)strnchr((char*)vURL, temp - vURL, ':');
     
      // Calculate username length and password length, including
      // null terminator (if the field exists)
      if(temp2 == NULL)
      {
         w = temp - vURL + 1;   // Username
         w2 = 0;               // Password
      }
      else
      {
         w = temp2 - vURL + 1;   // Username
         w2 = temp - temp2;      // Password
      }
     
      if(wUsernameLen)
      {
         if(vUsername)
         {
            if(*wUsernameLen < w)
               return 3;
            memcpy((void*)vUsername, (void*)vURL, w - 1);
            vUsername[w-1] = 0;
         }
         *wUsernameLen = w;
      }
   
      if(wPasswordLen)
      {
         if(vPassword)
         {
            if(*wPasswordLen < w2)
               return 3;
            if(w2)
            {
               memcpy((void*)vPassword, (void*)temp2+1, w2 - 1);
               vPassword[w2-1] = 0;
            }
         }
         *wPasswordLen = w2;
      }
   
      vURL += w;
      wURLLen -= w;
      if(w2)
      {
         vURL += w2;
         wURLLen -= w2;
      }
   }


   // Parse hostname field
   // Find the length of the hostname, including NULL
   // terminator
   temp = (BYTE*)strnchr((char*)vURL, wURLLen, ':');
   temp2 = (BYTE*)strnchr((char*)vURL, wURLLen, '/');
   if(temp && temp2)
   {
      if(temp > temp2)
         temp = NULL;
   }
   if(temp == NULL)
   {
      temp = temp2;
      if(temp2 == NULL)
         temp = vURL + wURLLen;
   }
   w = temp - vURL + 1;
   if(wHostnameLen)
   {
      if(vHostname)
      {
         if(*wHostnameLen < w)
            return 3;
         memcpy((void*)vHostname, (void*)vURL, w - 1);
         vHostname[w-1] = 0;
      }
      *wHostnameLen = w;
   }
   vURL += w - 1;
   wURLLen -= w - 1;


   // Parse port field
   if(*vURL == ':')
   {
      vURL++;
      wURLLen--;
      wLocalPort = 0;
      w = wURLLen;
      temp = (BYTE*)strnchr((char*)vURL, wURLLen, '/');
      if(temp != NULL)
         w = temp - vURL;
      w2 = w;
      if(wPort)
      {
         while(w--)
         {
            wLocalPort *= 10;
            wLocalPort += *vURL++ - '0';
         }
         *wPort = wLocalPort;
      }
      else
         vURL += w2;
      wURLLen -= w2;
   }
   else if(wPort)
      *wPort = wProtocolPorts[prot];


gokhangokcen



Joined: 30 Oct 2015
Posts: 4
Location: Turkey

View user's profile Send private message Send e-mail Visit poster's website

PostPosted: Mon May 21, 2018 9:10 am     Reply with quote

Code:

  // Parse file path field
   if(wFilePathLen)
   {
      w = ++wURLLen;
      if(wURLLen == 1u)
         w = 2;
      if(vFilePath)
      {
         if(*wFilePathLen < w)
            return 3;
         if(wURLLen == 1u)
            vFilePath[0] = '/';
         else
            memcpy((void*)vFilePath, (void*)vURL, wURLLen - 1);
         vFilePath[w - 1] = 0;
         *wFilePathLen = w;
         return 0;
      }
      *wFilePathLen = w;
   }
   return 0;
}
#endif


/*****************************************************************************
  Function:
   SHORT Replace(BYTE *vExpression, ROM BYTE *vFind, ROM BYTE *vReplacement,
              WORD wMaxLen, BOOL bSearchCaseInsensitive)

  Summary:
   Replaces all instances of a particular substring with a new string

  Description:
   Searches a string (vExpression) and replaces all instances of a particular
   substring (vFind) with a new string (vReplacement).  The start offset to
   being searching and a maximum number of replacements can be specified.  The
   search can be performed in a case sensitive or case insensitive manner.

  Precondition:
   This function is commented out by default to save code space because
   it is not used by any current stack features.  However, if you want to use
   it, go ahead and uncomment it.  It has been tested, so it (should) work
   correctly.

  Parameters:
   vExpression - Null terminated string to search and make replacements within.
   vFind - Null terminated string to search for.
   vReplacement - Null terminated string to replace all instances of vFind with.
   wMaxLen - Maximum length of the output vExpression string if string
      expansion is going to occur (replacement length is longer than find
      length).  If the replacements will cause this maximum string length to
      be exceeded, then no replacements will be made and a negative result
      will be returned, indicating failure.  If the replacement length is
      shorter or equal to the search length, then this parameter is ignored.
   bSearchCaseInsensitive - Boolean indicating if the search should be
      performed in a case insensitive manner.  Specify TRUE for case
      insensitive searches (slower) or FALSE for case sensitive
      searching (faster).

  Remarks:
   If the replacement string length is shorter than or equal to the search
   string length and the search string occurs in multiple overlapping
   locations (ex\: expression is "aaa", find is "aa", and replacement is "bb")
   then the first find match occuring when searching from left to right will
   be replaced.  (ex\: output expression will be "bba").
   
   However, if the replacement string length is longer than the search string
   length, the search will occur starting from the end of the string and
   proceed to the beginning (right to left searching).  In this case if the
   expression was "aaa", find was "aa", and replacement was "bbb", then the
   final output expression will be "abbb". 

  Returns:
   If zero or greater, indicates the count of how many replacements were made. 
   If less than zero (negative result), indicates that wMaxLen was too small
   to make the necessary replacements.  In this case, no replacements were
   made.
  ***************************************************************************/
#if 0
SHORT Replace(BYTE *vExpression, ROM BYTE *vFind, ROM BYTE *vReplacement, WORD wMaxLen, BOOL bSearchCaseInsensitive)
{
   WORD wExpressionLen, wFindLen, wFindLenMinusOne, wReplacementLen;
   WORD wFindCount, wReplacementsLeft;
   BYTE i, j;
   BYTE vFirstFindChar;
   WORD wBytesLeft;
   BYTE *vDest;
   BYTE *vExpressionCompare;
   ROM BYTE *vFindCompare;
   WORD w;

   wFindLen = strlenpgm((ROM char*)vFind);
   if(wFindLen == 0u)
      return 0;
   
   wExpressionLen = strlen((char*)vExpression);
   wReplacementLen = strlenpgm((ROM char*)vReplacement);

   wFindCount = 0;
   wFindLenMinusOne = wFindLen - 1;
   vFirstFindChar = *vFind++;
   if(bSearchCaseInsensitive)   // Convert to all lowercase if needed
      if((vFirstFindChar >= (BYTE)'A') && (vFirstFindChar <= (BYTE)'Z'))
         vFirstFindChar += 'a' - 'A';

   // If the replacement string is the same length as the search string, then
   // we can immediately do the needed replacements inline and return.
   if(wFindLen == wReplacementLen)
   {
      for(wBytesLeft = wExpressionLen; wBytesLeft; wBytesLeft--)
      {
         i = *vExpression++;
         if(bSearchCaseInsensitive)
         {
            if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
               i += 'a' - 'A';
            if(i != vFirstFindChar)
               continue;
            vExpressionCompare = vExpression;
            vFindCompare = vFind;
            w = wFindLenMinusOne;
            while(w)
            {
               i = *vExpressionCompare++;
               j = *vFindCompare++;
               if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
                  i += 'a' - 'A';
               if((j >= (BYTE)'A') && (j <= (BYTE)'Z'))
                  j += 'a' - 'A';
               if(i != j)
                  break;
               w--;
            }
            if(w)
               continue;
         }
         else
         {
            if(i != vFirstFindChar)
               continue;
            if(memcmppgm2ram((void*)vExpression, (ROM void*)vFind, wFindLenMinusOne))
               continue;
         }
   
         memcpypgm2ram((void*)vExpression-1, (ROM void*)vReplacement, wReplacementLen);
         wFindCount++;
         vExpression += wFindLenMinusOne;
         wBytesLeft -= wFindLenMinusOne;
      }
      return wFindCount;
   }
   
   
   // If the replacement string is shorter than the search string, then we can
   // search from left to right and move the string over as we find occurrences.
   if(wFindLen > wReplacementLen)
   {
      vDest = vExpression;
      for(wBytesLeft = wExpressionLen; wBytesLeft; wBytesLeft--)
      {
         i = *vExpression++;
         *vDest++ = i;
         if(bSearchCaseInsensitive)
         {
            if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
               i += 'a' - 'A';
            if(i != vFirstFindChar)
               continue;
            vExpressionCompare = vExpression;
            vFindCompare = vFind;
            w = wFindLenMinusOne;
            while(w)
            {
               i = *vExpressionCompare++;
               j = *vFindCompare++;
               if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
                  i += 'a' - 'A';
               if((j >= (BYTE)'A') && (j <= (BYTE)'Z'))
                  j += 'a' - 'A';
               if(i != j)
                  break;
               w--;
            }
            if(w)
               continue;
         }
         else
         {
            if(i != vFirstFindChar)
               continue;
            if(memcmppgm2ram((void*)vExpression, (ROM void*)vFind, wFindLenMinusOne))
               continue;
         }
   
         memcpypgm2ram((void*)vDest-1, (ROM void*)vReplacement, wReplacementLen);
         vDest += wReplacementLen-1;
         wFindCount++;
         vExpression += wFindLenMinusOne;
         wBytesLeft -= wFindLenMinusOne;
      }
      *vDest = 0x00;   // Write new null terminator since the string may have shrunk
      return wFindCount;
   }
   
   // If the replacement string is longer than the search string, then we will
   // take a two pass approach.  On the first pass, we will merely count how
   // many replacements to make.  With this we can calculate how long the
   // final string is going to be.  On the second pass, we will search from
   // right to left and expand the string as needed.

   // Pass 1: count how many occurrences of vFind are in vExpression
   for(wBytesLeft = wExpressionLen; wBytesLeft; wBytesLeft--)
   {
      i = *vExpression++;
      if(bSearchCaseInsensitive)
      {
         if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
            i += 'a' - 'A';
         if(i != vFirstFindChar)
            continue;
         vExpressionCompare = vExpression;
         vFindCompare = vFind;
         w = wFindLenMinusOne;
         while(w)
         {
            i = *vExpressionCompare++;
            j = *vFindCompare++;
            if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
               i += 'a' - 'A';
            if((j >= (BYTE)'A') && (j <= (BYTE)'Z'))
               j += 'a' - 'A';
            if(i != j)
               break;
            w--;
         }
         if(w)
            continue;
      }
      else
      {
         if(i != vFirstFindChar)
            continue;
         if(memcmppgm2ram((void*)vExpression, (ROM void*)vFind, wFindLenMinusOne))
            continue;
      }

      wFindCount++;
      vExpression += wFindLenMinusOne;
      wBytesLeft -= wFindLenMinusOne;
   }
   
   // Return immediately if no replacements are needed
   if(wFindCount == 0u)
      return 0;

   // Pass 2: make replacements and move string over
   vDest = vExpression + wFindCount * (wReplacementLen - wFindLen);
   if(vDest > vExpression - wExpressionLen + wMaxLen)
      return -1;
   *vDest-- = 0x00;   // Write new null terminator
   vExpression -= 1;
   vFind -= 1;
   vFirstFindChar = vFind[wFindLenMinusOne];
   if(bSearchCaseInsensitive)   // Convert to all lowercase if needed
      if((vFirstFindChar >= (BYTE)'A') && (vFirstFindChar <= (BYTE)'Z'))
         vFirstFindChar += 'a' - 'A';
   wReplacementsLeft = wFindCount;
   while(wReplacementsLeft)
   {
      i = *vExpression--;
      *vDest-- = i;
      if(bSearchCaseInsensitive)
      {
         if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
            i += 'a' - 'A';
         if(i != vFirstFindChar)
            continue;
         vExpressionCompare = vExpression;
         vFindCompare = &vFind[wFindLenMinusOne-1];
         w = wFindLenMinusOne;
         while(w)
         {
            i = *vExpressionCompare--;
            j = *vFindCompare--;
            if((i >= (BYTE)'A') && (i <= (BYTE)'Z'))
               i += 'a' - 'A';
            if((j >= (BYTE)'A') && (j <= (BYTE)'Z'))
               j += 'a' - 'A';
            if(i != j)
               break;
            w--;
         }
         if(w)
            continue;
      }
      else
      {
         if(i != vFirstFindChar)
            continue;
         if(memcmppgm2ram((void*)vExpression-wFindLenMinusOne, (ROM void*)vFind, wFindLenMinusOne))
            continue;
      }
      memcpypgm2ram((void*)vDest-wReplacementLen+2, (ROM void*)vReplacement, wReplacementLen);
      vDest -= wReplacementLen-1;

      vExpression -= wFindLenMinusOne;
      wBytesLeft -= wFindLenMinusOne;
      wReplacementsLeft--;
   }
   return wFindCount;
}
#endif

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