src/qcbor_encode.c

/*==============================================================================
 Copyright (c) 2016-2018, The Linux Foundation.
 Copyright (c) 2018-2020, Laurence Lundblade.
 All rights reserved.

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      disclaimer in the documentation and/or other materials provided
      with the distribution.
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      specific prior written permission.

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 =============================================================================*/


#include "qcbor/qcbor_encode.h"
#include "ieee754.h"


/**
 * @file qcbor_encode.c
 * 
 * The entire implementation of the QCBOR encoder.
 */


/*
 * == Nesting Tracking ==
 *
 * The following functions and data type QCBORTrackNesting implement
 * the nesting management for encoding.
 *
 * CBOR's two nesting types, arrays and maps, are tracked here. There
 * is a limit of QCBOR_MAX_ARRAY_NESTING to the number of arrays and
 * maps that can be nested in one encoding so the encoding context
 * stays small enough to fit on the stack.
 *
 * When an array/map is opened, pCurrentNesting points to the element
 * in pArrays that records the type, start position and accumulates a
 * count of the number of items added. When closed the start position
 * is used to go back and fill in the type and number of items in the
 * array/map.
 *
 * Encoded output can be a CBOR Sequence (RFC 8742) in which case
 * there is no top-level array or map. It starts out with a string,
 * integer or other non-aggregate type. It may have an array or map
 * other than at the start, in which case that nesting is tracked
 * here.
 *
 * QCBOR has a special feature to allow constructing byte string
 * wrapped CBOR directly into the output buffer, so no extra buffer is
 * needed for byte string wrapping.  This is implemented as nesting
 * with the type CBOR_MAJOR_TYPE_BYTE_STRING and is tracked here. Byte
 * string wrapped CBOR is used by COSE for data that is to be hashed.
 */
inline static void Nesting_Init(QCBORTrackNesting *pNesting)
{
   /* Assumes pNesting has been zeroed. */
   pNesting->pCurrentNesting = &pNesting->pArrays[0];
   /* Implied CBOR array at the top nesting level. This is never
    * returned, but makes the item count work correctly.
    */
   pNesting->pCurrentNesting->uMajorType = CBOR_MAJOR_TYPE_ARRAY;
}

inline static uint8_t Nesting_Increase(QCBORTrackNesting *pNesting,
                                          uint8_t uMajorType,
                                          uint32_t uPos)
{
   if(pNesting->pCurrentNesting == &pNesting->pArrays[QCBOR_MAX_ARRAY_NESTING]) {
      return QCBOR_ERR_ARRAY_NESTING_TOO_DEEP;
   } else {
      pNesting->pCurrentNesting++;
      pNesting->pCurrentNesting->uCount     = 0;
      pNesting->pCurrentNesting->uStart     = uPos;
      pNesting->pCurrentNesting->uMajorType = uMajorType;
      return QCBOR_SUCCESS;
   }
}

inline static void Nesting_Decrease(QCBORTrackNesting *pNesting)
{
   pNesting->pCurrentNesting--;
}

inline static uint8_t Nesting_Increment(QCBORTrackNesting *pNesting)
{
#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
   if(1 >= QCBOR_MAX_ITEMS_IN_ARRAY - pNesting->pCurrentNesting->uCount) {
      return QCBOR_ERR_ARRAY_TOO_LONG;
   }
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */

   pNesting->pCurrentNesting->uCount++;

   return QCBOR_SUCCESS;
}

inline static uint16_t Nesting_GetCount(QCBORTrackNesting *pNesting)
{
   /* The nesting count recorded is always the actual number of
    * individual data items in the array or map. For arrays CBOR uses
    * the actual item count. For maps, CBOR uses the number of pairs.
    * This function returns the number needed for the CBOR encoding,
    * so it divides the number of items by two for maps to get the
    * number of pairs.
    */
   if(pNesting->pCurrentNesting->uMajorType == CBOR_MAJOR_TYPE_MAP) {
      /* Cast back to uint16_t after integer promotion from bit shift */
      return (uint16_t)(pNesting->pCurrentNesting->uCount >> 1);
   } else {
      return pNesting->pCurrentNesting->uCount;
   }
}

inline static uint32_t Nesting_GetStartPos(QCBORTrackNesting *pNesting)
{
   return pNesting->pCurrentNesting->uStart;
}

#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
inline static uint8_t Nesting_GetMajorType(QCBORTrackNesting *pNesting)
{
   return pNesting->pCurrentNesting->uMajorType;
}

inline static bool Nesting_IsInNest(QCBORTrackNesting *pNesting)
{
   return pNesting->pCurrentNesting == &pNesting->pArrays[0] ? false : true;
}
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */




/*
 * == Major CBOR Types ==
 *
 * Encoding of the major CBOR types is by these functions:
 *
 * CBOR Major Type    Public Function
 * 0                  QCBOREncode_AddUInt64()
 * 0, 1               QCBOREncode_AddUInt64(), QCBOREncode_AddInt64()
 * 2, 3               QCBOREncode_AddBuffer()
 * 4, 5               QCBOREncode_OpenMapOrArray(), QCBOREncode_CloseMapOrArray(),
 *                    QCBOREncode_OpenMapOrArrayIndefiniteLength(),
 *                    QCBOREncode_CloseMapOrArrayIndefiniteLength()
 * 6                  QCBOREncode_AddTag()
 * 7                  QCBOREncode_AddDouble(), QCBOREncode_AddFloat(),
 *                    QCBOREncode_AddDoubleNoPreferred(),
 *                    QCBOREncode_AddFloatNoPreferred(), QCBOREncode_AddType7()
 *
 * Additionally, encoding of decimal fractions and bigfloats is by
 * QCBOREncode_AddExponentAndMantissa() and byte strings that wrap
 * encoded CBOR are handled by QCBOREncode_OpenMapOrArray() and
 * QCBOREncode_CloseBstrWrap2().
 *
 *
 * == Error Tracking Plan ==
 *
 * Errors are tracked internally and not returned until
 * QCBOREncode_Finish() or QCBOREncode_GetErrorState() is called. The
 * CBOR errors are in me->uError.  UsefulOutBuf also tracks whether
 * the buffer is full or not in its context.  Once either of these
 * errors is set they are never cleared. Only QCBOREncode_Init()
 * resets them. Or said another way, they must never be cleared or
 * we'll tell the caller all is good when it is not.
 *
 * Only one error code is reported by QCBOREncode_Finish() even if
 * there are multiple errors. The last one set wins. The caller might
 * have to fix one error to reveal the next one they have to fix.
 * This is OK.
 *
 * The buffer full error tracked by UsefulBuf is only pulled out of
 * UsefulBuf in QCBOREncode_Finish() so it is the one that usually
 * wins.  UsefulBuf will never go off the end of the buffer even if it
 * is called again and again when full.
 *
 * QCBOR_DISABLE_ENCODE_USAGE_GUARDS disables about half of the error
 * checks here to reduce code size by about 150 bytes leaving only the
 * checks for size to avoid buffer overflow. If the calling code is
 * completely correct, checks are completely unnecessary.  For
 * example, there is no need to check that all the opens are matched
 * by a close.
 *
 * QCBOR_DISABLE_ENCODE_USAGE_GUARDS also disables the check for more
 * than QCBOR_MAX_ITEMS_IN_ARRAY in an array. Since
 * QCBOR_MAX_ITEMS_IN_ARRAY is very large (65,535) it is very unlikely
 * to be reached. If it is reached, the count will wrap around to zero
 * and CBOR that is not well formed will be produced, but there will
 * be no buffers overrun and new security issues in the code.
 *
 * The 8 errors returned here fall into three categories:
 *
 * Sizes
 *   QCBOR_ERR_BUFFER_TOO_LARGE        -- Encoded output exceeded UINT32_MAX
 *   QCBOR_ERR_BUFFER_TOO_SMALL        -- Output buffer too small
 *   QCBOR_ERR_ARRAY_NESTING_TOO_DEEP  -- Nesting > QCBOR_MAX_ARRAY_NESTING1
 *   QCBOR_ERR_ARRAY_TOO_LONG          -- Too many items added to an array/map [1]
 *
 * Nesting constructed incorrectly
 *   QCBOR_ERR_TOO_MANY_CLOSES         -- More close calls than opens [1]
 *   QCBOR_ERR_CLOSE_MISMATCH          -- Type of close does not match open [1]
 *   QCBOR_ERR_ARRAY_OR_MAP_STILL_OPEN -- Finish called without enough closes [1]
 *
 * Would generate not-well-formed CBOR
 *   QCBOR_ERR_ENCODE_UNSUPPORTED      -- Simple type between 24 and 31 [1]
 *
 * [1] indicated disabled by QCBOR_DISABLE_ENCODE_USAGE_GUARDS
 */


/*
 Public function for initialization. See qcbor/qcbor_encode.h
 */
void QCBOREncode_Init(QCBOREncodeContext *me, UsefulBuf Storage)
{
   memset(me, 0, sizeof(QCBOREncodeContext));
   UsefulOutBuf_Init(&(me->OutBuf), Storage);
   Nesting_Init(&(me->nesting));
}


/*
 * Public function to encode a CBOR head. See qcbor/qcbor_encode.h
 */
UsefulBufC QCBOREncode_EncodeHead(UsefulBuf buffer,
                                  uint8_t   uMajorType,
                                  uint8_t   uMinLen,
                                  uint64_t  uArgument)
{
   /*
    * == Description of the CBOR Head ==
    *
    *    The head of a CBOR data item
    *  +---+-----+ +--------+ +--------+ +--------+      +--------+
    *  |M T|  A R G U M E N T . . .                               |
    *  +---+-----+ +--------+ +--------+ +--------+ ...  +--------+
    *
    * Every CBOR data item has a "head". It is made up of the "major
    * type" and the "argument".
    *
    * The major type indicates whether the data item is an integer,
    * string, array or such. It is encoded in 3 bits giving it a range
    * from 0 to 7.  0 indicates the major type is a positive integer,
    * 1 a negative integer, 2 a byte string and so on.
    *
    * These 3 bits are the first part of the "initial byte" in a data
    * item.  Every data item has an initial byte, and some only have
    * the initial byte.
    *
    * The argument is essentially a number between 0 and UINT64_MAX
    * (18446744073709551615). This number is interpreted to mean
    * different things for the different major types. For major type
    * 0, a positive integer, it is value of the data item. For major
    * type 2, a byte string, it is the length in bytes of the byte
    * string. For major type 4, an array, it is the number of data
    * items in the array.
    *
    * Special encoding is used so that the argument values less than
    * 24 can be encoded very compactly in the same byte as the major
    * type is encoded. When the lower 5 bits of the initial byte have
    * a value less than 24, then that is the value of the argument.
    *
    * If the lower 5 bits of the initial byte are less than 24, then
    * they are the value of the argument. This allows integer values 0
    * - 23 to be CBOR encoded in just one byte.
    *
    * When the value of lower 5 bits are 24, 25, 26, or 27 the
    * argument is encoded in 1, 2, 4 or 8 bytes following the initial
    * byte in network byte order (bit endian). The cases when it is
    * 28, 29 and 30 are reserved for future use. The value 31 is a
    * special indicator for indefinite length strings, arrays and
    * maps.
    *
    * The lower 5 bits are called the "additional information."
    *
    * Thus the CBOR head may be 1, 2, 3, 5 or 9 bytes long.
    *
    * It is legal in CBOR to encode the argument using any of these
    * lengths even if it could be encoded in a shorter length. For
    * example it is legal to encode a data item representing the
    * positive integer 0 in 9 bytes even though it could be encoded in
    * only 0. This is legal to allow for for very simple code or even
    * hardware-only implementations that just output a register
    * directly.
    *
    * CBOR defines preferred encoding as the encoding of the argument
    * in the smallest number of bytes needed to encode it.
    *
    * This function takes the major type and argument as inputs and
    * outputs the encoded CBOR head for them. It does conversion to
    * network byte order.  It implements CBOR preferred encoding,
    * outputting the shortest representation of the argument.
    *
    * == Endian Conversion ==
    *
    * This code does endian conversion without hton() or knowing the
    * endianness of the machine by using masks and shifts. This avoids
    * the dependency on hton() and the mess of figuring out how to
    * find the machine's endianness.
    *
    * This is a good efficient implementation on little-endian
    * machines.  A faster and smaller implementation is possible on
    * big-endian machines because CBOR/network byte order is
    * big-endian. However big-endian machines are uncommon.
    *
    * On x86, this is about 150 bytes instead of 500 bytes for the
    * original, more formal unoptimized code.
    *
    * This also does the CBOR preferred shortest encoding for integers
    * and is called to do endian conversion for floats.
    *
    * It works backwards from the least significant byte to the most
    * significant byte.
    *
    * == Floating Point ==
    *
    * When the major type is 7 and the 5 lower bits have the values
    * 25, 26 or 27, the argument is a floating-point number that is
    * half, single or double-precision. Note that it is not the
    * conversion from a floating-point value to an integer value like
    * converting 0x00 to 0.00, it is the interpretation of the bits in
    * the argument as an IEEE 754 float-point number.
    *
    * Floating-point numbers must be converted to network byte
    * order. That is accomplished here by exactly the same code that
    * converts integer arguments to network byte order.
    *
    * There is preferred encoding for floating-point numbers in CBOR,
    * but it is very different than for integers and it is not
    * implemented here.  Half-precision is preferred to
    * single-precision which is preferred to double-precision only if
    * the conversion can be performed without loss of precision. Zero
    * and infinity can always be converted to half-precision, without
    * loss but 3.141592653589 cannot.
    *
    * The way this function knows to not do preferred encoding on the
    * argument passed here when it is a floating point number is the
    * uMinLen parameter. It should be 2, 4 or 8 for half, single and
    * double precision floating point values. This prevents and the
    * incorrect removal of leading zeros when encoding arguments that
    * are floating-point numbers.
    *
    * == Use of Type int and Static Analyzers ==
    *
    * The type int is used here for several variables because of the
    * way integer promotion works in C for variables that are uint8_t
    * or uint16_t. The basic rule is that they will always be promoted
    * to int if they will fit. These integer variables here need only
    * hold values less than 255 so they will always fit into an int.
    *
    * Most of values stored are never negative, so one might think
    * that unsigned int would be more correct than int. However the C
    * integer promotion rules only promote to unsigned int if the
    * result won't fit into an int even if the promotion is for an
    * unsigned variable like uint8_t.
    *
    * By declaring these int, there are few implicit conversions and
    * fewer casts needed. Code size is reduced a little. It makes
    * static analyzers happier.
    *
    * Note also that declaring these uint8_t won't stop integer wrap
    * around if the code is wrong. It won't make the code more
    * correct.
    *
    * https://stackoverflow.com/questions/46073295/implicit-type-promotion-rules
    * https://stackoverflow.com/questions/589575/what-does-the-c-standard-state-the-size-of-int-long-type-to-be
    *
    * Code Reviewers: THIS FUNCTION DOES POINTER MATH
    */

   /* The buffer must have room for the largest CBOR HEAD + one
    * extra. The one extra is needed for this code to work as it does
    * a pre-decrement.
    */
    if(buffer.len < QCBOR_HEAD_BUFFER_SIZE) {
        return NULLUsefulBufC;
    }

   /* Pointer to last valid byte in the buffer */
   uint8_t * const pBufferEnd = &((uint8_t *)buffer.ptr)[QCBOR_HEAD_BUFFER_SIZE-1];

   /* Point to the last byte and work backwards */
   uint8_t *pByte = pBufferEnd;
   /* The 5 bits in the initial byte that are not the major type */
   int nAdditionalInfo;

   if(uMajorType > QCBOR_INDEFINITE_LEN_TYPE_MODIFIER) {
      /* Special case for start & end of indefinite length */
      uMajorType  = uMajorType - QCBOR_INDEFINITE_LEN_TYPE_MODIFIER;
      /* This takes advantage of design of CBOR where additional info
       * is 31 for both opening and closing indefinite length
       * maps and arrays.
       */
       #if CBOR_SIMPLE_BREAK != LEN_IS_INDEFINITE
       #error additional info for opening array not the same as for closing
       #endif
      nAdditionalInfo = CBOR_SIMPLE_BREAK;

   } else if (uArgument < CBOR_TWENTY_FOUR && uMinLen == 0) {
      /* Simple case where argument is < 24 */
      nAdditionalInfo = (int)uArgument;

   } else  {
      /* This encodes the argument in 1,2,4 or 8 bytes. The outer loop
       * runs once for 1 byte and 4 times for 8 bytes.  The inner loop
       * runs 1, 2 or 4 times depending on outer loop counter. This
       * works backwards shifting 8 bits off the argument being
       * encoded at a time until all bits from uArgument have been
       * encoded and the minimum encoding size is reached.  Minimum
       * encoding size is for floating-point numbers that have some
       * zero-value bytes that must be output.
       */
      static const uint8_t aIterate[] = {1,1,2,4};

      /* uMinLen passed in is unsigned, but goes negative in the loop
       * so it must be converted to a signed value.
       */
      int nMinLen = (int)uMinLen;
      int i;
      for(i = 0; uArgument || nMinLen > 0; i++) {
         const int nIterations = (int)aIterate[i];
         for(int j = 0; j < nIterations; j++) {
            *--pByte = (uint8_t)(uArgument & 0xff);
            uArgument = uArgument >> 8;
         }
         nMinLen -= nIterations;
      }

      nAdditionalInfo = LEN_IS_ONE_BYTE-1 + i;
   }

   /* This expression integer-promotes to type int. The code above in
    * function guarantees that nAdditionalInfo will never be larger
    * than 0x1f. The caller may pass in a too-large uMajor type. The
    * conversion to unint8_t will cause an integer wrap around and
    * incorrect CBOR will be generated, but no security issue will
    * occur.
    */
   const int nInitialByte = (uMajorType << 5) + nAdditionalInfo;
   *--pByte = (uint8_t)nInitialByte;

#ifdef EXTRA_ENCODE_HEAD_CHECK
   /* This is a sanity check that can be turned on to verify the
    * pointer math in this function is not going wrong. Turn it on and
    * run the whole test suite to perform the check.
    */
   if(pBufferEnd - pByte > 9 || pBufferEnd - pByte < 1 || pByte < (uint8_t *)buffer.ptr) {
      return NULLUsefulBufC;
   }
#endif /* EXTRA_ENCODE_HEAD_CHECK */

   /* Length will not go negative because the loops run for at most 8 decrements
    * of pByte, only one other decrement is made, and the array is sized
    * for this.
    */
   return (UsefulBufC){pByte, (size_t)(pBufferEnd - pByte)};
}


/**
 * @brief Append the CBOR head, the major type and argument
 *
 * @param me          Encoder context.
 * @param uMajorType  Major type to insert.
 * @param uArgument   The argument (an integer value or a length).
 * @param uMinLen     The minimum number of bytes for encoding the CBOR argument.
 *
 * This formats the CBOR "head" and appends it to the output.
 */
static void AppendCBORHead(QCBOREncodeContext *me, uint8_t uMajorType,  uint64_t uArgument, uint8_t uMinLen)
{
   /* A stack buffer large enough for a CBOR head */
   UsefulBuf_MAKE_STACK_UB  (pBufferForEncodedHead, QCBOR_HEAD_BUFFER_SIZE);

   UsefulBufC EncodedHead = QCBOREncode_EncodeHead(pBufferForEncodedHead,
                                                    uMajorType,
                                                    uMinLen,
                                                    uArgument);

   /* No check for EncodedHead == NULLUsefulBufC is performed here to
    * save object code. It is very clear that pBufferForEncodedHead is
    * the correct size. If EncodedHead == NULLUsefulBufC then
    * UsefulOutBuf_AppendUsefulBuf() will do nothing so there is no
    * security hole introduced.
    */

   UsefulOutBuf_AppendUsefulBuf(&(me->OutBuf), EncodedHead);
}


/**
 * @brief Insert the CBOR head for a map, array or wrapped bstr
 *
 * @param me          QCBOR encoding context.
 * @param uMajorType  One of CBOR_MAJOR_TYPE_XXXX.
 * @param uLen        The length of the data item.
 *
 * When an array, map or bstr was opened, nothing was done but note
 * the position. This function goes back to that position and inserts
 * the CBOR Head with the major type and length.
 */
static void InsertCBORHead(QCBOREncodeContext *me, uint8_t uMajorType, size_t uLen)
{
#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
   if(me->uError == QCBOR_SUCCESS) {
      if(!Nesting_IsInNest(&(me->nesting))) {
         me->uError = QCBOR_ERR_TOO_MANY_CLOSES;
         return;
      } else if(Nesting_GetMajorType(&(me->nesting)) != uMajorType) {
         me->uError = QCBOR_ERR_CLOSE_MISMATCH;
         return;
      }
   }
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */

   /* A stack buffer large enough for a CBOR head */
   UsefulBuf_MAKE_STACK_UB(pBufferForEncodedHead, QCBOR_HEAD_BUFFER_SIZE);

   UsefulBufC EncodedHead = QCBOREncode_EncodeHead(pBufferForEncodedHead,
                                                   uMajorType,
                                                   0,
                                                   uLen);

   /* No check for EncodedHead == NULLUsefulBufC is performed here to
    * save object code. It is very clear that pBufferForEncodedHead is
    * the correct size. If EncodedHead == NULLUsefulBufC then
    * UsefulOutBuf_InsertUsefulBuf() will do nothing so there is no
    * security whole introduced.
    */
   UsefulOutBuf_InsertUsefulBuf(&(me->OutBuf),
                                EncodedHead,
                                Nesting_GetStartPos(&(me->nesting)));

   Nesting_Decrease(&(me->nesting));
}


/**
 * @brief Increment item counter for maps and arrays.
 *
 * @param pMe          QCBOR encoding context.
 *
 * This is mostly a separate function to make code more readable and
 * to have fewer occurrences of #ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
 */
static inline void IncrementMapOrArrayCount(QCBOREncodeContext *pMe)
{
#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
   if(pMe->uError == QCBOR_SUCCESS) {
      pMe->uError = Nesting_Increment(&(pMe->nesting));
   }
#else
   (void)Nesting_Increment(&(pMe->nesting));
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */
}


/*
 * Public functions for adding unsigned integers. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddUInt64(QCBOREncodeContext *me, uint64_t uValue)
{
   AppendCBORHead(me, CBOR_MAJOR_TYPE_POSITIVE_INT, uValue, 0);

   IncrementMapOrArrayCount(me);
}


/*
 * Public functions for adding signed integers. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddInt64(QCBOREncodeContext *me, int64_t nNum)
{
   uint8_t  uMajorType;
   uint64_t uValue;

   if(nNum < 0) {
      /* In CBOR -1 encodes as 0x00 with major type negative int. */
      uValue = (uint64_t)(-nNum - 1);
      uMajorType = CBOR_MAJOR_TYPE_NEGATIVE_INT;
   } else {
      uValue = (uint64_t)nNum;
      uMajorType = CBOR_MAJOR_TYPE_POSITIVE_INT;
   }
   AppendCBORHead(me, uMajorType, uValue, 0);

   IncrementMapOrArrayCount(me);
}


/*
 * Semi-private function. It is exposed to user of the interface, but
 * one of its inline wrappers will usually be called instead of this.
 *
 * See qcbor/qcbor_encode.h
 *
 * This does the work of adding actual strings bytes to the CBOR
 * output (as opposed to adding numbers and opening / closing
 * aggregate types).

 * There are four use cases:
 *   CBOR_MAJOR_TYPE_BYTE_STRING -- Byte strings
 *   CBOR_MAJOR_TYPE_TEXT_STRING -- Text strings
 *   CBOR_MAJOR_NONE_TYPE_RAW -- Already-encoded CBOR
 *   CBOR_MAJOR_NONE_TYPE_BSTR_LEN_ONLY -- Special case
 *
 * The first two add the head plus the actual bytes. The third just
 * adds the bytes as the heas is presumed to be in the bytes. The
 * fourth just adds the head for the very special case of
 * QCBOREncode_AddBytesLenOnly().
 */
void QCBOREncode_AddBuffer(QCBOREncodeContext *me, uint8_t uMajorType, UsefulBufC Bytes)
{
   /* If it is not Raw CBOR, add the type and the length */
   if(uMajorType != CBOR_MAJOR_NONE_TYPE_RAW) {
      uint8_t uRealMajorType = uMajorType;
      if(uRealMajorType == CBOR_MAJOR_NONE_TYPE_BSTR_LEN_ONLY) {
         uRealMajorType = CBOR_MAJOR_TYPE_BYTE_STRING;
      }
      AppendCBORHead(me, uRealMajorType, Bytes.len, 0);
   }

   if(uMajorType != CBOR_MAJOR_NONE_TYPE_BSTR_LEN_ONLY) {
      /* Actually add the bytes */
      UsefulOutBuf_AppendUsefulBuf(&(me->OutBuf), Bytes);
   }

   IncrementMapOrArrayCount(me);
}


/*
 * Public functions for adding a tag. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddTag(QCBOREncodeContext *me, uint64_t uTag)
{
   AppendCBORHead(me, CBOR_MAJOR_TYPE_OPTIONAL, uTag, 0);
}


/*
 * Semi-private function. It is exposed to user of the interface, but
 * one of its inline wrappers will usually be called instead of this.
 *
 * See header qcbor/qcbor_encode.h
 */
void QCBOREncode_AddType7(QCBOREncodeContext *me, uint8_t uMinLen, uint64_t uNum)
{
#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
   if(me->uError == QCBOR_SUCCESS) {
      if(uNum >= CBOR_SIMPLEV_RESERVED_START && uNum <= CBOR_SIMPLEV_RESERVED_END) {
         me->uError = QCBOR_ERR_ENCODE_UNSUPPORTED;
         return;
      }
   }
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */

   /* AppendCBORHead() does endian swapping for the float / double */
   AppendCBORHead(me, CBOR_MAJOR_TYPE_SIMPLE, uNum, uMinLen);
   
   IncrementMapOrArrayCount(me);
}


/*
 * Public functions for adding a double. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddDoubleNoPreferred(QCBOREncodeContext *me, double dNum)
{
   QCBOREncode_AddType7(me,
                        sizeof(uint64_t),
                        UsefulBufUtil_CopyDoubleToUint64(dNum));
}


/*
 * Public functions for adding a double. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddDouble(QCBOREncodeContext *me, double dNum)
{
#ifndef QCBOR_DISABLE_PREFERRED_FLOAT
   const IEEE754_union uNum = IEEE754_DoubleToSmallest(dNum);

   QCBOREncode_AddType7(me, uNum.uSize, uNum.uValue);
#else /* QCBOR_DISABLE_PREFERRED_FLOAT */
   QCBOREncode_AddDoubleNoPreferred(me, dNum);
#endif /* QCBOR_DISABLE_PREFERRED_FLOAT */
}


/*
 * Public functions for adding a float. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddFloatNoPreferred(QCBOREncodeContext *me, float fNum)
{
   QCBOREncode_AddType7(me,
                        sizeof(uint32_t),
                        UsefulBufUtil_CopyFloatToUint32(fNum));
}


/*
 * Public functions for adding a float. See qcbor/qcbor_encode.h
 */
void QCBOREncode_AddFloat(QCBOREncodeContext *me, float fNum)
{
#ifndef QCBOR_DISABLE_PREFERRED_FLOAT
   const IEEE754_union uNum = IEEE754_FloatToSmallest(fNum);

   QCBOREncode_AddType7(me, uNum.uSize, uNum.uValue);
#else /* QCBOR_DISABLE_PREFERRED_FLOAT */
   QCBOREncode_AddFloatNoPreferred(me, fNum);
#endif /* QCBOR_DISABLE_PREFERRED_FLOAT */
}


#ifndef QCBOR_CONFIG_DISABLE_EXP_AND_MANTISSA
/*
 * Semi-public function. It is exposed to the user of the interface,
 * but one of the inline wrappers will usually be called rather than
 * this.
 *
 * See qcbor/qcbor_encode.h
 *
 * Improvement: create another version of this that only takes a big
 * number mantissa and converts the output to a type 0 or 1 integer
 * when mantissa is small enough.
 */
void QCBOREncode_AddExponentAndMantissa(QCBOREncodeContext *pMe,
                                        uint64_t            uTag,
                                        UsefulBufC          BigNumMantissa,
                                        bool                bBigNumIsNegative,
                                        int64_t             nMantissa,
                                        int64_t             nExponent)
{
   /* This is for encoding either a big float or a decimal fraction,
    * both of which are an array of two items, an exponent and a
    * mantissa.  The difference between the two is that the exponent
    * is base-2 for big floats and base-10 for decimal fractions, but
    * that has no effect on the code here.
    */
   if(uTag != CBOR_TAG_INVALID64) {
      QCBOREncode_AddTag(pMe, uTag);
   }
   QCBOREncode_OpenArray(pMe);
   QCBOREncode_AddInt64(pMe, nExponent);
   if(!UsefulBuf_IsNULLC(BigNumMantissa)) {
      if(bBigNumIsNegative) {
         QCBOREncode_AddNegativeBignum(pMe, BigNumMantissa);
      } else {
         QCBOREncode_AddPositiveBignum(pMe, BigNumMantissa);
      }
   } else {
      QCBOREncode_AddInt64(pMe, nMantissa);
   }
   QCBOREncode_CloseArray(pMe);
}
#endif /* QCBOR_CONFIG_DISABLE_EXP_AND_MANTISSA */


/*
 * Semi-public function. It is exposed to the user of the interface,
 * but one of the inline wrappers will usually be called rather than
 * this.
 *
 * See qcbor/qcbor_encode.h
*/
void QCBOREncode_OpenMapOrArray(QCBOREncodeContext *me, uint8_t uMajorType)
{
   /* Add one item to the nesting level we are in for the new map or array */
   IncrementMapOrArrayCount(me);

   /* The offset where the length of an array or map will get written
    * is stored in a uint32_t, not a size_t to keep stack usage
    * smaller. This checks to be sure there is no wrap around when
    * recording the offset.  Note that on 64-bit machines CBOR larger
    * than 4GB can be encoded as long as no array/map offsets occur
    * past the 4GB mark, but the public interface says that the
    * maximum is 4GB to keep the discussion simpler.
    */
   size_t uEndPosition = UsefulOutBuf_GetEndPosition(&(me->OutBuf));

   /* QCBOR_MAX_ARRAY_OFFSET is slightly less than UINT32_MAX so this
    * code can run on a 32-bit machine and tests can pass on a 32-bit
    * machine. If it was exactly UINT32_MAX, then this code would not
    * compile or run on a 32-bit machine and an #ifdef or some machine
    * size detection would be needed reducing portability.
    */
   if(uEndPosition >= QCBOR_MAX_ARRAY_OFFSET) {
      me->uError = QCBOR_ERR_BUFFER_TOO_LARGE;

   } else {
      /* Increase nesting level because this is a map or array.  Cast
       * from size_t to uin32_t is safe because of check above.
       */
      me->uError = Nesting_Increase(&(me->nesting), uMajorType, (uint32_t)uEndPosition);
   }
}


/*
 * Semi-public function. It is exposed to the user of the interface,
 * but one of the inline wrappers will usually be called rather than
 * this.
 *
 * See qcbor/qcbor_encode.h
 */
void QCBOREncode_OpenMapOrArrayIndefiniteLength(QCBOREncodeContext *me, uint8_t uMajorType)
{
   /* Insert the indefinite length marker (0x9f for arrays, 0xbf for maps) */
   AppendCBORHead(me, uMajorType, 0, 0);

   /* Call the definite-length opener just to do the bookkeeping for
    * nesting.  It will record the position of the opening item in the
    * encoded output but this is not used when closing this open.
    */
   QCBOREncode_OpenMapOrArray(me, uMajorType);
}


/*
 * Public functions for closing arrays and maps. See qcbor/qcbor_encode.h
 */
void QCBOREncode_CloseMapOrArray(QCBOREncodeContext *me, uint8_t uMajorType)
{
   InsertCBORHead(me, uMajorType, Nesting_GetCount(&(me->nesting)));
}


/*
 * Public functions for closing bstr wrapping. See qcbor/qcbor_encode.h
 */
void QCBOREncode_CloseBstrWrap2(QCBOREncodeContext *me, bool bIncludeCBORHead, UsefulBufC *pWrappedCBOR)
{
   const size_t uInsertPosition = Nesting_GetStartPos(&(me->nesting));
   const size_t uEndPosition    = UsefulOutBuf_GetEndPosition(&(me->OutBuf));

   /* This subtraction can't go negative because the UsefulOutBuf
    * always only grows and never shrinks. UsefulOutBut itself also
    * has defenses such that it won't write where it should not even
    * if given incorrect input lengths.
    */
   const size_t uBstrLen = uEndPosition - uInsertPosition;

   /* Actually insert */
   InsertCBORHead(me, CBOR_MAJOR_TYPE_BYTE_STRING, uBstrLen);

   if(pWrappedCBOR) {
      /* Return pointer and length to the enclosed encoded CBOR. The
       * intended use is for it to be hashed (e.g., SHA-256) in a COSE
       * implementation.  This must be used right away, as the pointer
       * and length go invalid on any subsequent calls to this
       * function because there might be calls to
       * InsertEncodedTypeAndNumber() that slides data to the right.
       */
      size_t uStartOfNew = uInsertPosition;
      if(!bIncludeCBORHead) {
         /* Skip over the CBOR head to just get the inserted bstr */
         const size_t uNewEndPosition = UsefulOutBuf_GetEndPosition(&(me->OutBuf));
         uStartOfNew += uNewEndPosition - uEndPosition;
      }
      const UsefulBufC PartialResult = UsefulOutBuf_OutUBuf(&(me->OutBuf));
      *pWrappedCBOR = UsefulBuf_Tail(PartialResult, uStartOfNew);
   }
}


/*
 * Public functions for closing arrays and maps. See qcbor/qcbor_encode.h
 */
void QCBOREncode_CloseMapOrArrayIndefiniteLength(QCBOREncodeContext *me, uint8_t uMajorType)
{
#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
   if(me->uError == QCBOR_SUCCESS) {
      if(!Nesting_IsInNest(&(me->nesting))) {
         me->uError = QCBOR_ERR_TOO_MANY_CLOSES;
         return;
      } else if(Nesting_GetMajorType(&(me->nesting)) != uMajorType) {
         me->uError = QCBOR_ERR_CLOSE_MISMATCH;
         return;
      }
   }
#else /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */
   (void) uMajorType;
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */

   /* Append the break marker (0xff for both arrays and maps) */
   AppendCBORHead(me, CBOR_MAJOR_NONE_TYPE_SIMPLE_BREAK, CBOR_SIMPLE_BREAK, 0);
   Nesting_Decrease(&(me->nesting));
}


/*
 * Public functions to finish and get the encoded result. See qcbor/qcbor_encode.h
 */
QCBORError QCBOREncode_Finish(QCBOREncodeContext *me, UsefulBufC *pEncodedCBOR)
{
   QCBORError uReturn = QCBOREncode_GetErrorState(me);

   if(uReturn != QCBOR_SUCCESS) {
      goto Done;
   }

#ifndef QCBOR_DISABLE_ENCODE_USAGE_GUARDS
   if(Nesting_IsInNest(&(me->nesting))) {
      uReturn = QCBOR_ERR_ARRAY_OR_MAP_STILL_OPEN;
      goto Done;
   }
#endif /* QCBOR_DISABLE_ENCODE_USAGE_GUARDS */

   *pEncodedCBOR = UsefulOutBuf_OutUBuf(&(me->OutBuf));

Done:
   return uReturn;
}


/*
 * Public functions to get size of the encoded result. See qcbor/qcbor_encode.h
 */
QCBORError QCBOREncode_FinishGetSize(QCBOREncodeContext *me, size_t *puEncodedLen)
{
   UsefulBufC Enc;

   QCBORError nReturn = QCBOREncode_Finish(me, &Enc);

   if(nReturn == QCBOR_SUCCESS) {
      *puEncodedLen = Enc.len;
   }

   return nReturn;
}