src/hb-cff-interp-common.hh - third_party/harfbuzz - Git at Google

 /*
  * Copyright © 2018 Adobe Inc.
  *
  *  This is part of HarfBuzz, a text shaping library.
  *
  * Permission is hereby granted, without written agreement and without
  * license or royalty fees, to use, copy, modify, and distribute this
  * software and its documentation for any purpose, provided that the
  * above copyright notice and the following two paragraphs appear in
  * all copies of this software.
  *
  * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
  * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
  * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
  * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
  * DAMAGE.
  *
  * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
  * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
  * FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE PROVIDED HEREUNDER IS
  * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
  * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
  *
  * Adobe Author(s): Michiharu Ariza
  */
 #ifndef HB_CFF_INTERP_COMMON_HH
 #define HB_CFF_INTERP_COMMON_HH

 extern HB_INTERNAL const unsigned char *endchar_str;

 namespace CFF {

 using namespace OT;

 typedef unsigned int op_code_t;


 /* === Dict operators === */

 /* One byte operators (0-31) */
 #define OpCode_version		  0 /* CFF Top */
 #define OpCode_Notice		  1 /* CFF Top */
 #define OpCode_FullName		  2 /* CFF Top */
 #define OpCode_FamilyName	  3 /* CFF Top */
 #define OpCode_Weight		  4 /* CFF Top */
 #define OpCode_FontBBox		  5 /* CFF Top */
 #define OpCode_BlueValues	  6 /* CFF Private, CFF2 Private */
 #define OpCode_OtherBlues	  7 /* CFF Private, CFF2 Private */
 #define OpCode_FamilyBlues	  8 /* CFF Private, CFF2 Private */
 #define OpCode_FamilyOtherBlues	  9 /* CFF Private, CFF2 Private */
 #define OpCode_StdHW		 10 /* CFF Private, CFF2 Private */
 #define OpCode_StdVW		 11 /* CFF Private, CFF2 Private */
 #define OpCode_escape		 12 /* All. Shared with CS */
 #define OpCode_UniqueID		 13 /* CFF Top */
 #define OpCode_XUID		 14 /* CFF Top */
 #define OpCode_charset		 15 /* CFF Top (0) */
 #define OpCode_Encoding		 16 /* CFF Top (0) */
 #define OpCode_CharStrings	 17 /* CFF Top, CFF2 Top */
 #define OpCode_Private		 18 /* CFF Top, CFF2 FD */
 #define OpCode_Subrs		 19 /* CFF Private, CFF2 Private */
 #define OpCode_defaultWidthX	 20 /* CFF Private (0) */
 #define OpCode_nominalWidthX	 21 /* CFF Private (0) */
 #define OpCode_vsindexdict	 22 /* CFF2 Private/CS */
 #define OpCode_blenddict	 23 /* CFF2 Private/CS */
 #define OpCode_vstore		 24 /* CFF2 Top */
 #define OpCode_reserved25	 25
 #define OpCode_reserved26	 26
 #define OpCode_reserved27	 27

 /* Numbers */
 #define OpCode_shortint		 28 /* 16-bit integer, All */
 #define OpCode_longintdict	 29 /* 32-bit integer, All */
 #define OpCode_BCD		 30 /* Real number, CFF2 Top/FD */
 #define OpCode_reserved31	 31

 /* 1-byte integers */
 #define OpCode_OneByteIntFirst	 32 /* All. beginning of the range of first byte ints */
 #define OpCode_OneByteIntLast	246 /* All. ending of the range of first byte int */

 /* 2-byte integers */
 #define OpCode_TwoBytePosInt0	247 /* All. first byte of two byte positive int (+108 to +1131) */
 #define OpCode_TwoBytePosInt1	248
 #define OpCode_TwoBytePosInt2	249
 #define OpCode_TwoBytePosInt3	250

 #define OpCode_TwoByteNegInt0	251 /* All. first byte of two byte negative int (-1131 to -108) */
 #define OpCode_TwoByteNegInt1	252
 #define OpCode_TwoByteNegInt2	253
 #define OpCode_TwoByteNegInt3	254

 /* Two byte escape operators 12, (0-41) */
 #define OpCode_ESC_Base		256
 #define Make_OpCode_ESC(byte2)	((op_code_t)(OpCode_ESC_Base + (byte2)))

 inline op_code_t Unmake_OpCode_ESC (op_code_t op)  { return (op_code_t)(op - OpCode_ESC_Base); }
 inline bool Is_OpCode_ESC (op_code_t op) { return op >= OpCode_ESC_Base; }
 inline unsigned int OpCode_Size (op_code_t op) { return Is_OpCode_ESC (op) ? 2: 1; }

 #define OpCode_Copyright	Make_OpCode_ESC(0) /* CFF Top */
 #define OpCode_isFixedPitch	Make_OpCode_ESC(1) /* CFF Top (false) */
 #define OpCode_ItalicAngle	Make_OpCode_ESC(2) /* CFF Top (0) */
 #define OpCode_UnderlinePosition Make_OpCode_ESC(3) /* CFF Top (-100) */
 #define OpCode_UnderlineThickness Make_OpCode_ESC(4) /* CFF Top (50) */
 #define OpCode_PaintType	Make_OpCode_ESC(5) /* CFF Top (0) */
 #define OpCode_CharstringType	Make_OpCode_ESC(6) /* CFF Top (2) */
 #define OpCode_FontMatrix	Make_OpCode_ESC(7) /* CFF Top, CFF2 Top (.001 0 0 .001 0 0)*/
 #define OpCode_StrokeWidth	Make_OpCode_ESC(8) /* CFF Top (0) */
 #define OpCode_BlueScale	Make_OpCode_ESC(9) /* CFF Private, CFF2 Private (0.039625) */
 #define OpCode_BlueShift	Make_OpCode_ESC(10) /* CFF Private, CFF2 Private (7) */
 #define OpCode_BlueFuzz		Make_OpCode_ESC(11) /* CFF Private, CFF2 Private (1) */
 #define OpCode_StemSnapH	Make_OpCode_ESC(12) /* CFF Private, CFF2 Private */
 #define OpCode_StemSnapV	Make_OpCode_ESC(13) /* CFF Private, CFF2 Private */
 #define OpCode_ForceBold	Make_OpCode_ESC(14) /* CFF Private (false) */
 #define OpCode_reservedESC15	Make_OpCode_ESC(15)
 #define OpCode_reservedESC16	Make_OpCode_ESC(16)
 #define OpCode_LanguageGroup	Make_OpCode_ESC(17) /* CFF Private, CFF2 Private (0) */
 #define OpCode_ExpansionFactor	Make_OpCode_ESC(18) /* CFF Private, CFF2 Private (0.06) */
 #define OpCode_initialRandomSeed Make_OpCode_ESC(19) /* CFF Private (0) */
 #define OpCode_SyntheticBase	Make_OpCode_ESC(20) /* CFF Top */
 #define OpCode_PostScript	Make_OpCode_ESC(21) /* CFF Top */
 #define OpCode_BaseFontName	Make_OpCode_ESC(22) /* CFF Top */
 #define OpCode_BaseFontBlend	Make_OpCode_ESC(23) /* CFF Top */
 #define OpCode_reservedESC24	Make_OpCode_ESC(24)
 #define OpCode_reservedESC25	Make_OpCode_ESC(25)
 #define OpCode_reservedESC26	Make_OpCode_ESC(26)
 #define OpCode_reservedESC27	Make_OpCode_ESC(27)
 #define OpCode_reservedESC28	Make_OpCode_ESC(28)
 #define OpCode_reservedESC29	Make_OpCode_ESC(29)
 #define OpCode_ROS		Make_OpCode_ESC(30) /* CFF Top_CID */
 #define OpCode_CIDFontVersion	Make_OpCode_ESC(31) /* CFF Top_CID (0) */
 #define OpCode_CIDFontRevision	Make_OpCode_ESC(32) /* CFF Top_CID (0) */
 #define OpCode_CIDFontType	Make_OpCode_ESC(33) /* CFF Top_CID (0) */
 #define OpCode_CIDCount		Make_OpCode_ESC(34) /* CFF Top_CID (8720) */
 #define OpCode_UIDBase		Make_OpCode_ESC(35) /* CFF Top_CID */
 #define OpCode_FDArray		Make_OpCode_ESC(36) /* CFF Top_CID, CFF2 Top */
 #define OpCode_FDSelect		Make_OpCode_ESC(37) /* CFF Top_CID, CFF2 Top */
 #define OpCode_FontName		Make_OpCode_ESC(38) /* CFF Top_CID */


 /* === CharString operators === */

 #define OpCode_hstem		  1 /* CFF, CFF2 */
 #define OpCode_Reserved2	  2
 #define OpCode_vstem		  3 /* CFF, CFF2 */
 #define OpCode_vmoveto		  4 /* CFF, CFF2 */
 #define OpCode_rlineto		  5 /* CFF, CFF2 */
 #define OpCode_hlineto		  6 /* CFF, CFF2 */
 #define OpCode_vlineto		  7 /* CFF, CFF2 */
 #define OpCode_rrcurveto	  8 /* CFF, CFF2 */
 #define OpCode_Reserved9	  9
 #define OpCode_callsubr		 10 /* CFF, CFF2 */
 #define OpCode_return		 11 /* CFF */
 //#define OpCode_escape		 12 /* CFF, CFF2 */
 #define OpCode_Reserved13	 13
 #define OpCode_endchar		 14 /* CFF */
 #define OpCode_vsindexcs	 15 /* CFF2 */
 #define OpCode_blendcs		 16 /* CFF2 */
 #define OpCode_Reserved17	 17
 #define OpCode_hstemhm		 18 /* CFF, CFF2 */
 #define OpCode_hintmask		 19 /* CFF, CFF2 */
 #define OpCode_cntrmask		 20 /* CFF, CFF2 */
 #define OpCode_rmoveto		 21 /* CFF, CFF2 */
 #define OpCode_hmoveto		 22 /* CFF, CFF2 */
 #define OpCode_vstemhm		 23 /* CFF, CFF2 */
 #define OpCode_rcurveline	 24 /* CFF, CFF2 */
 #define OpCode_rlinecurve	 25 /* CFF, CFF2 */
 #define OpCode_vvcurveto	 26 /* CFF, CFF2 */
 #define OpCode_hhcurveto	 27 /* CFF, CFF2 */
 //#define OpCode_shortint	 28 /* CFF, CFF2 */
 #define OpCode_callgsubr	 29 /* CFF, CFF2 */
 #define OpCode_vhcurveto	 30 /* CFF, CFF2 */
 #define OpCode_hvcurveto	 31 /* CFF, CFF2 */

 #define OpCode_fixedcs		255 /* 32-bit fixed */

 /* Two byte escape operators 12, (0-41) */
 #define OpCode_dotsection	Make_OpCode_ESC(0) /* CFF (obsoleted) */
 #define OpCode_ReservedESC1	Make_OpCode_ESC(1)
 #define OpCode_ReservedESC2	Make_OpCode_ESC(2)
 #define OpCode_and		Make_OpCode_ESC(3) /* CFF */
 #define OpCode_or		Make_OpCode_ESC(4) /* CFF */
 #define OpCode_not		Make_OpCode_ESC(5) /* CFF */
 #define OpCode_ReservedESC6	Make_OpCode_ESC(6)
 #define OpCode_ReservedESC7	Make_OpCode_ESC(7)
 #define OpCode_ReservedESC8	Make_OpCode_ESC(8)
 #define OpCode_abs		Make_OpCode_ESC(9) /* CFF */
 #define OpCode_add		Make_OpCode_ESC(10) /* CFF */
 #define OpCode_sub		Make_OpCode_ESC(11) /* CFF */
 #define OpCode_div		Make_OpCode_ESC(12) /* CFF */
 #define OpCode_ReservedESC13	Make_OpCode_ESC(13)
 #define OpCode_neg		Make_OpCode_ESC(14) /* CFF */
 #define OpCode_eq		Make_OpCode_ESC(15) /* CFF */
 #define OpCode_ReservedESC16	Make_OpCode_ESC(16)
 #define OpCode_ReservedESC17	Make_OpCode_ESC(17)
 #define OpCode_drop		Make_OpCode_ESC(18) /* CFF */
 #define OpCode_ReservedESC19	Make_OpCode_ESC(19)
 #define OpCode_put		Make_OpCode_ESC(20) /* CFF */
 #define OpCode_get		Make_OpCode_ESC(21) /* CFF */
 #define OpCode_ifelse		Make_OpCode_ESC(22) /* CFF */
 #define OpCode_random		Make_OpCode_ESC(23) /* CFF */
 #define OpCode_mul		Make_OpCode_ESC(24) /* CFF */
 //#define OpCode_reservedESC25	Make_OpCode_ESC(25)
 #define OpCode_sqrt		Make_OpCode_ESC(26) /* CFF */
 #define OpCode_dup		Make_OpCode_ESC(27) /* CFF */
 #define OpCode_exch		Make_OpCode_ESC(28) /* CFF */
 #define OpCode_index		Make_OpCode_ESC(29) /* CFF */
 #define OpCode_roll		Make_OpCode_ESC(30) /* CFF */
 #define OpCode_reservedESC31	Make_OpCode_ESC(31)
 #define OpCode_reservedESC32	Make_OpCode_ESC(32)
 #define OpCode_reservedESC33	Make_OpCode_ESC(33)
 #define OpCode_hflex		Make_OpCode_ESC(34) /* CFF, CFF2 */
 #define OpCode_flex		Make_OpCode_ESC(35) /* CFF, CFF2 */
 #define OpCode_hflex1		Make_OpCode_ESC(36) /* CFF, CFF2 */
 #define OpCode_flex1		Make_OpCode_ESC(37) /* CFF, CFF2 */


 #define OpCode_Invalid		0xFFFFu


 struct number_t
 {
   void set_int (int v)       { value = v; }
   int to_int () const        { return value; }

   void set_fixed (int32_t v) { value = v / 65536.0; }
   int32_t to_fixed () const  { return value * 65536.0; }

   void set_real (double v)   { value = v; }
   double to_real () const    { return value; }

   bool in_int_range () const
   { return ((double) (int16_t) to_int () == value); }

   bool operator >  (const number_t &n) const { return value > n.to_real (); }
   bool operator <  (const number_t &n) const { return n > *this; }
   bool operator >= (const number_t &n) const { return !(*this < n); }
   bool operator <= (const number_t &n) const { return !(*this > n); }

   const number_t &operator += (const number_t &n)
   {
     set_real (to_real () + n.to_real ());

     return *this;
   }

   protected:
   double value = 0.;
 };

 /* byte string */
 struct UnsizedByteStr : UnsizedArrayOf <HBUINT8>
 {
   hb_ubytes_t as_ubytes (unsigned l) const
   { return hb_ubytes_t ((const unsigned char *) this, l); }

   // encode 2-byte int (Dict/CharString) or 4-byte int (Dict)
   template <typename T, typename V>
   static bool serialize_int (hb_serialize_context_t *c, op_code_t intOp, V value)
   {
     TRACE_SERIALIZE (this);

     HBUINT8 *p = c->allocate_size<HBUINT8> (1);
     if (unlikely (!p)) return_trace (false);
     *p = intOp;

     T *ip = c->allocate_size<T> (T::static_size);
     if (unlikely (!ip)) return_trace (false);
     return_trace (c->check_assign (*ip, value, HB_SERIALIZE_ERROR_INT_OVERFLOW));
   }

   template <typename V>
   static bool serialize_int4 (hb_serialize_context_t *c, V value)
   { return serialize_int<HBINT32> (c, OpCode_longintdict, value); }

   template <typename V>
   static bool serialize_int2 (hb_serialize_context_t *c, V value)
   { return serialize_int<HBINT16> (c, OpCode_shortint, value); }

   /* Defining null_size allows a Null object may be created. Should be safe because:
    * A descendent struct Dict uses a Null pointer to indicate a missing table,
    * checked before access.
    */
   DEFINE_SIZE_MIN(0);
 };

 /* A byte string associated with the current offset and an error condition */
 struct byte_str_ref_t
 {
   byte_str_ref_t ()
     : str () {}

   byte_str_ref_t (const hb_ubytes_t &str_, unsigned int offset_ = 0)
     : str (str_) { set_offset (offset_); }

   void reset (const hb_ubytes_t &str_, unsigned int offset_ = 0)
   {
     str = str_;
     set_offset (offset_);
   }

   const unsigned char& operator [] (int i) {
     if (unlikely ((unsigned int) (get_offset () + i) >= str.length))
     {
       set_error ();
       return Null (unsigned char);
     }
     return str.arrayZ[get_offset () + i];
   }

   unsigned char head_unchecked () const { return str.arrayZ[get_offset ()]; }

   /* Conversion to hb_ubytes_t */
   operator hb_ubytes_t () const { return str.sub_array (get_offset ()); }

   hb_ubytes_t sub_array (unsigned int offset_, unsigned int len_) const
   { return str.sub_array (offset_, len_); }

   bool avail (unsigned int count=1) const
   { return get_offset () + count <= str.length; }
   void inc (unsigned int count=1)
   {
     /* Automatically puts us in error if count is out-of-range. */
     set_offset (get_offset () + count);
   }

   /* We (ab)use ubytes backwards_length as a cursor (called offset),
    * as well as to store error condition. */

   unsigned get_offset () const { return str.backwards_length; }
   void set_offset (unsigned offset) { str.backwards_length = offset; }

   void set_error ()      { str.backwards_length = str.length + 1; }
   bool in_error () const { return str.backwards_length > str.length; }

   unsigned total_size () const { return str.length; }

   protected:
   hb_ubytes_t       str;
 };

 /* stack */
 template <typename ELEM, int LIMIT>
 struct cff_stack_t
 {
   ELEM& operator [] (unsigned int i)
   {
     if (unlikely (i >= count))
     {
       set_error ();
       return Crap (ELEM);
     }
     return elements[i];
   }

   void push (const ELEM &v)
   {
     if (likely (count < LIMIT))
       elements[count++] = v;
     else
       set_error ();
   }
   ELEM &push ()
   {
     if (likely (count < LIMIT))
       return elements[count++];
     else
     {
       set_error ();
       return Crap (ELEM);
     }
   }

   ELEM& pop ()
   {
     if (likely (count > 0))
       return elements[--count];
     else
     {
       set_error ();
       return Crap (ELEM);
     }
   }
   void pop (unsigned int n)
   {
     if (likely (count >= n))
       count -= n;
     else
       set_error ();
   }

   const ELEM& peek ()
   {
     if (unlikely (count == 0))
     {
       set_error ();
       return Null (ELEM);
     }
     return elements[count - 1];
   }

   void unpop ()
   {
     if (likely (count < LIMIT))
       count++;
     else
       set_error ();
   }

   void clear () { count = 0; }

   bool in_error () const { return (error); }
   void set_error ()      { error = true; }

   unsigned int get_count () const { return count; }
   bool is_empty () const          { return !count; }

   hb_array_t<const ELEM> sub_array (unsigned start, unsigned length) const
   { return hb_array_t<const ELEM> (elements).sub_array (start, length); }

   private:
   bool error = false;
   unsigned int count = 0;
   ELEM elements[LIMIT];
 };

 /* argument stack */
 template <typename ARG=number_t>
 struct arg_stack_t : cff_stack_t<ARG, 513>
 {
   void push_int (int v)
   {
     ARG &n = S::push ();
     n.set_int (v);
   }

   void push_fixed (int32_t v)
   {
     ARG &n = S::push ();
     n.set_fixed (v);
   }

   void push_real (double v)
   {
     ARG &n = S::push ();
     n.set_real (v);
   }

   ARG& pop_num () { return this->pop (); }

   int pop_int ()  { return this->pop ().to_int (); }

   unsigned int pop_uint ()
   {
     int i = pop_int ();
     if (unlikely (i < 0))
     {
       i = 0;
       S::set_error ();
     }
     return (unsigned) i;
   }

   void push_longint_from_substr (byte_str_ref_t& str_ref)
   {
     push_int ((str_ref[0] << 24) | (str_ref[1] << 16) | (str_ref[2] << 8) | (str_ref[3]));
     str_ref.inc (4);
   }

   bool push_fixed_from_substr (byte_str_ref_t& str_ref)
   {
     if (unlikely (!str_ref.avail (4)))
       return false;
     push_fixed ((int32_t)*(const HBUINT32*)&str_ref[0]);
     str_ref.inc (4);
     return true;
   }

   private:
   typedef cff_stack_t<ARG, 513> S;
 };

 /* an operator prefixed by its operands in a byte string */
 struct op_str_t
 {
   /* This used to have a hb_ubytes_t. Using a pointer and length
    * in a particular order, saves 8 bytes in this struct and more
    * in our parsed_cs_op_t subclass. */

   const unsigned char *ptr = nullptr;

   op_code_t  op = OpCode_Invalid;

   uint8_t length = 0;
 };

 /* base of OP_SERIALIZER */
 struct op_serializer_t
 {
   protected:
   bool copy_opstr (hb_serialize_context_t *c, const op_str_t& opstr) const
   {
     TRACE_SERIALIZE (this);

     unsigned char *d = c->allocate_size<unsigned char> (opstr.length);
     if (unlikely (!d)) return_trace (false);
     /* Faster than hb_memcpy for small strings. */
     for (unsigned i = 0; i < opstr.length; i++)
       d[i] = opstr.ptr[i];
     return_trace (true);
   }
 };

 template <typename VAL>
 struct parsed_values_t
 {
   void init ()
   {
     opStart = 0;
     values.init ();
   }
   void fini () { values.fini (); }

   void alloc (unsigned n)
   {
     values.alloc (n, true);
   }

   void add_op (op_code_t op, const byte_str_ref_t& str_ref = byte_str_ref_t (), const VAL &v = VAL ())
   {
     VAL *val = values.push (v);
     val->op = op;
     auto arr = str_ref.sub_array (opStart, str_ref.get_offset () - opStart);
     val->ptr = arr.arrayZ;
     val->length = arr.length;
     opStart = str_ref.get_offset ();
   }

   bool has_op (op_code_t op) const
   {
     for (const auto& v : values)
       if (v.op == op) return true;
     return false;
   }

   unsigned get_count () const { return values.length; }
   const VAL &operator [] (unsigned int i) const { return values[i]; }

   unsigned int       opStart;
   hb_vector_t<VAL>   values;
 };

 template <typename ARG=number_t>
 struct interp_env_t
 {
   interp_env_t () {}
   interp_env_t (const hb_ubytes_t &str_)
   {
     str_ref.reset (str_);
   }
   bool in_error () const
   { return str_ref.in_error () || argStack.in_error (); }

   void set_error () { str_ref.set_error (); }

   op_code_t fetch_op ()
   {
     op_code_t  op = OpCode_Invalid;
     if (unlikely (!str_ref.avail ()))
       return OpCode_Invalid;
     op = (op_code_t) str_ref.head_unchecked ();
     str_ref.inc ();
     if (op == OpCode_escape) {
       if (unlikely (!str_ref.avail ()))
 	return OpCode_Invalid;
       op = Make_OpCode_ESC (str_ref.head_unchecked ());
       str_ref.inc ();
     }
     return op;
   }

   const ARG& eval_arg (unsigned int i) { return argStack[i]; }

   ARG& pop_arg () { return argStack.pop (); }
   void pop_n_args (unsigned int n) { argStack.pop (n); }

   void clear_args () { pop_n_args (argStack.get_count ()); }

   byte_str_ref_t
 		str_ref;
   arg_stack_t<ARG>
 		argStack;
 };

 using num_interp_env_t =  interp_env_t<>;

 template <typename ARG=number_t>
 struct opset_t
 {
   static void process_op (op_code_t op, interp_env_t<ARG>& env)
   {
     switch (op) {
       case OpCode_shortint:
 	env.argStack.push_int ((int16_t)((env.str_ref[0] << 8) | env.str_ref[1]));
 	env.str_ref.inc (2);
 	break;

       case OpCode_TwoBytePosInt0: case OpCode_TwoBytePosInt1:
       case OpCode_TwoBytePosInt2: case OpCode_TwoBytePosInt3:
 	env.argStack.push_int ((int16_t)((op - OpCode_TwoBytePosInt0) * 256 + env.str_ref[0] + 108));
 	env.str_ref.inc ();
 	break;

       case OpCode_TwoByteNegInt0: case OpCode_TwoByteNegInt1:
       case OpCode_TwoByteNegInt2: case OpCode_TwoByteNegInt3:
 	env.argStack.push_int ((-(int16_t)(op - OpCode_TwoByteNegInt0) * 256 - env.str_ref[0] - 108));
 	env.str_ref.inc ();
 	break;

       default:
 	/* 1-byte integer */
 	if (likely ((OpCode_OneByteIntFirst <= op) && (op <= OpCode_OneByteIntLast)))
 	{
 	  env.argStack.push_int ((int)op - 139);
 	} else {
 	  /* invalid unknown operator */
 	  env.clear_args ();
 	  env.set_error ();
 	}
 	break;
     }
   }
 };

 template <typename ENV>
 struct interpreter_t
 {
   interpreter_t (ENV& env_) : env (env_) {}
   ENV& env;
 };

 } /* namespace CFF */

 #endif /* HB_CFF_INTERP_COMMON_HH */
	/*
	* Copyright © 2018 Adobe Inc.
	*
	* This is part of HarfBuzz, a text shaping library.
	*
	* Permission is hereby granted, without written agreement and without
	* license or royalty fees, to use, copy, modify, and distribute this
	* software and its documentation for any purpose, provided that the
	* above copyright notice and the following two paragraphs appear in
	* all copies of this software.
	*
	* IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
	* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
	* ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
	* IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
	* DAMAGE.
	*
	* THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
	* BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
	* FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS
	* ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
	* PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
	*
	* Adobe Author(s): Michiharu Ariza
	*/
	#ifndef HB_CFF_INTERP_COMMON_HH
	#define HB_CFF_INTERP_COMMON_HH

	extern HB_INTERNAL const unsigned char *endchar_str;

	namespace CFF {

	using namespace OT;

	typedef unsigned int op_code_t;


	/* === Dict operators === */

	/* One byte operators (0-31) */
	#define OpCode_version 0 /* CFF Top */
	#define OpCode_Notice 1 /* CFF Top */
	#define OpCode_FullName 2 /* CFF Top */
	#define OpCode_FamilyName 3 /* CFF Top */
	#define OpCode_Weight 4 /* CFF Top */
	#define OpCode_FontBBox 5 /* CFF Top */
	#define OpCode_BlueValues 6 /* CFF Private, CFF2 Private */
	#define OpCode_OtherBlues 7 /* CFF Private, CFF2 Private */
	#define OpCode_FamilyBlues 8 /* CFF Private, CFF2 Private */
	#define OpCode_FamilyOtherBlues 9 /* CFF Private, CFF2 Private */
	#define OpCode_StdHW 10 /* CFF Private, CFF2 Private */
	#define OpCode_StdVW 11 /* CFF Private, CFF2 Private */
	#define OpCode_escape 12 /* All. Shared with CS */
	#define OpCode_UniqueID 13 /* CFF Top */
	#define OpCode_XUID 14 /* CFF Top */
	#define OpCode_charset 15 /* CFF Top (0) */
	#define OpCode_Encoding 16 /* CFF Top (0) */
	#define OpCode_CharStrings 17 /* CFF Top, CFF2 Top */
	#define OpCode_Private 18 /* CFF Top, CFF2 FD */
	#define OpCode_Subrs 19 /* CFF Private, CFF2 Private */
	#define OpCode_defaultWidthX 20 /* CFF Private (0) */
	#define OpCode_nominalWidthX 21 /* CFF Private (0) */
	#define OpCode_vsindexdict 22 /* CFF2 Private/CS */
	#define OpCode_blenddict 23 /* CFF2 Private/CS */
	#define OpCode_vstore 24 /* CFF2 Top */
	#define OpCode_reserved25 25
	#define OpCode_reserved26 26
	#define OpCode_reserved27 27

	/* Numbers */
	#define OpCode_shortint 28 /* 16-bit integer, All */
	#define OpCode_longintdict 29 /* 32-bit integer, All */
	#define OpCode_BCD 30 /* Real number, CFF2 Top/FD */
	#define OpCode_reserved31 31

	/* 1-byte integers */
	#define OpCode_OneByteIntFirst 32 /* All. beginning of the range of first byte ints */
	#define OpCode_OneByteIntLast 246 /* All. ending of the range of first byte int */

	/* 2-byte integers */
	#define OpCode_TwoBytePosInt0 247 /* All. first byte of two byte positive int (+108 to +1131) */
	#define OpCode_TwoBytePosInt1 248
	#define OpCode_TwoBytePosInt2 249
	#define OpCode_TwoBytePosInt3 250

	#define OpCode_TwoByteNegInt0 251 /* All. first byte of two byte negative int (-1131 to -108) */
	#define OpCode_TwoByteNegInt1 252
	#define OpCode_TwoByteNegInt2 253
	#define OpCode_TwoByteNegInt3 254

	/* Two byte escape operators 12, (0-41) */
	#define OpCode_ESC_Base 256
	#define Make_OpCode_ESC(byte2) ((op_code_t)(OpCode_ESC_Base + (byte2)))

	inline op_code_t Unmake_OpCode_ESC (op_code_t op) { return (op_code_t)(op - OpCode_ESC_Base); }
	inline bool Is_OpCode_ESC (op_code_t op) { return op >= OpCode_ESC_Base; }
	inline unsigned int OpCode_Size (op_code_t op) { return Is_OpCode_ESC (op) ? 2: 1; }

	#define OpCode_Copyright Make_OpCode_ESC(0) /* CFF Top */
	#define OpCode_isFixedPitch Make_OpCode_ESC(1) /* CFF Top (false) */
	#define OpCode_ItalicAngle Make_OpCode_ESC(2) /* CFF Top (0) */
	#define OpCode_UnderlinePosition Make_OpCode_ESC(3) /* CFF Top (-100) */
	#define OpCode_UnderlineThickness Make_OpCode_ESC(4) /* CFF Top (50) */
	#define OpCode_PaintType Make_OpCode_ESC(5) /* CFF Top (0) */
	#define OpCode_CharstringType Make_OpCode_ESC(6) /* CFF Top (2) */
	#define OpCode_FontMatrix Make_OpCode_ESC(7) /* CFF Top, CFF2 Top (.001 0 0 .001 0 0)*/
	#define OpCode_StrokeWidth Make_OpCode_ESC(8) /* CFF Top (0) */
	#define OpCode_BlueScale Make_OpCode_ESC(9) /* CFF Private, CFF2 Private (0.039625) */
	#define OpCode_BlueShift Make_OpCode_ESC(10) /* CFF Private, CFF2 Private (7) */
	#define OpCode_BlueFuzz Make_OpCode_ESC(11) /* CFF Private, CFF2 Private (1) */
	#define OpCode_StemSnapH Make_OpCode_ESC(12) /* CFF Private, CFF2 Private */
	#define OpCode_StemSnapV Make_OpCode_ESC(13) /* CFF Private, CFF2 Private */
	#define OpCode_ForceBold Make_OpCode_ESC(14) /* CFF Private (false) */
	#define OpCode_reservedESC15 Make_OpCode_ESC(15)
	#define OpCode_reservedESC16 Make_OpCode_ESC(16)
	#define OpCode_LanguageGroup Make_OpCode_ESC(17) /* CFF Private, CFF2 Private (0) */
	#define OpCode_ExpansionFactor Make_OpCode_ESC(18) /* CFF Private, CFF2 Private (0.06) */
	#define OpCode_initialRandomSeed Make_OpCode_ESC(19) /* CFF Private (0) */
	#define OpCode_SyntheticBase Make_OpCode_ESC(20) /* CFF Top */
	#define OpCode_PostScript Make_OpCode_ESC(21) /* CFF Top */
	#define OpCode_BaseFontName Make_OpCode_ESC(22) /* CFF Top */
	#define OpCode_BaseFontBlend Make_OpCode_ESC(23) /* CFF Top */
	#define OpCode_reservedESC24 Make_OpCode_ESC(24)
	#define OpCode_reservedESC25 Make_OpCode_ESC(25)
	#define OpCode_reservedESC26 Make_OpCode_ESC(26)
	#define OpCode_reservedESC27 Make_OpCode_ESC(27)
	#define OpCode_reservedESC28 Make_OpCode_ESC(28)
	#define OpCode_reservedESC29 Make_OpCode_ESC(29)
	#define OpCode_ROS Make_OpCode_ESC(30) /* CFF Top_CID */
	#define OpCode_CIDFontVersion Make_OpCode_ESC(31) /* CFF Top_CID (0) */
	#define OpCode_CIDFontRevision Make_OpCode_ESC(32) /* CFF Top_CID (0) */
	#define OpCode_CIDFontType Make_OpCode_ESC(33) /* CFF Top_CID (0) */
	#define OpCode_CIDCount Make_OpCode_ESC(34) /* CFF Top_CID (8720) */
	#define OpCode_UIDBase Make_OpCode_ESC(35) /* CFF Top_CID */
	#define OpCode_FDArray Make_OpCode_ESC(36) /* CFF Top_CID, CFF2 Top */
	#define OpCode_FDSelect Make_OpCode_ESC(37) /* CFF Top_CID, CFF2 Top */
	#define OpCode_FontName Make_OpCode_ESC(38) /* CFF Top_CID */


	/* === CharString operators === */

	#define OpCode_hstem 1 /* CFF, CFF2 */
	#define OpCode_Reserved2 2
	#define OpCode_vstem 3 /* CFF, CFF2 */
	#define OpCode_vmoveto 4 /* CFF, CFF2 */
	#define OpCode_rlineto 5 /* CFF, CFF2 */
	#define OpCode_hlineto 6 /* CFF, CFF2 */
	#define OpCode_vlineto 7 /* CFF, CFF2 */
	#define OpCode_rrcurveto 8 /* CFF, CFF2 */
	#define OpCode_Reserved9 9
	#define OpCode_callsubr 10 /* CFF, CFF2 */
	#define OpCode_return 11 /* CFF */
	//#define OpCode_escape 12 /* CFF, CFF2 */
	#define OpCode_Reserved13 13
	#define OpCode_endchar 14 /* CFF */
	#define OpCode_vsindexcs 15 /* CFF2 */
	#define OpCode_blendcs 16 /* CFF2 */
	#define OpCode_Reserved17 17
	#define OpCode_hstemhm 18 /* CFF, CFF2 */
	#define OpCode_hintmask 19 /* CFF, CFF2 */
	#define OpCode_cntrmask 20 /* CFF, CFF2 */
	#define OpCode_rmoveto 21 /* CFF, CFF2 */
	#define OpCode_hmoveto 22 /* CFF, CFF2 */
	#define OpCode_vstemhm 23 /* CFF, CFF2 */
	#define OpCode_rcurveline 24 /* CFF, CFF2 */
	#define OpCode_rlinecurve 25 /* CFF, CFF2 */
	#define OpCode_vvcurveto 26 /* CFF, CFF2 */
	#define OpCode_hhcurveto 27 /* CFF, CFF2 */
	//#define OpCode_shortint 28 /* CFF, CFF2 */
	#define OpCode_callgsubr 29 /* CFF, CFF2 */
	#define OpCode_vhcurveto 30 /* CFF, CFF2 */
	#define OpCode_hvcurveto 31 /* CFF, CFF2 */

	#define OpCode_fixedcs 255 /* 32-bit fixed */

	/* Two byte escape operators 12, (0-41) */
	#define OpCode_dotsection Make_OpCode_ESC(0) /* CFF (obsoleted) */
	#define OpCode_ReservedESC1 Make_OpCode_ESC(1)
	#define OpCode_ReservedESC2 Make_OpCode_ESC(2)
	#define OpCode_and Make_OpCode_ESC(3) /* CFF */
	#define OpCode_or Make_OpCode_ESC(4) /* CFF */
	#define OpCode_not Make_OpCode_ESC(5) /* CFF */
	#define OpCode_ReservedESC6 Make_OpCode_ESC(6)
	#define OpCode_ReservedESC7 Make_OpCode_ESC(7)
	#define OpCode_ReservedESC8 Make_OpCode_ESC(8)
	#define OpCode_abs Make_OpCode_ESC(9) /* CFF */
	#define OpCode_add Make_OpCode_ESC(10) /* CFF */
	#define OpCode_sub Make_OpCode_ESC(11) /* CFF */
	#define OpCode_div Make_OpCode_ESC(12) /* CFF */
	#define OpCode_ReservedESC13 Make_OpCode_ESC(13)
	#define OpCode_neg Make_OpCode_ESC(14) /* CFF */
	#define OpCode_eq Make_OpCode_ESC(15) /* CFF */
	#define OpCode_ReservedESC16 Make_OpCode_ESC(16)
	#define OpCode_ReservedESC17 Make_OpCode_ESC(17)
	#define OpCode_drop Make_OpCode_ESC(18) /* CFF */
	#define OpCode_ReservedESC19 Make_OpCode_ESC(19)
	#define OpCode_put Make_OpCode_ESC(20) /* CFF */
	#define OpCode_get Make_OpCode_ESC(21) /* CFF */
	#define OpCode_ifelse Make_OpCode_ESC(22) /* CFF */
	#define OpCode_random Make_OpCode_ESC(23) /* CFF */
	#define OpCode_mul Make_OpCode_ESC(24) /* CFF */
	//#define OpCode_reservedESC25 Make_OpCode_ESC(25)
	#define OpCode_sqrt Make_OpCode_ESC(26) /* CFF */
	#define OpCode_dup Make_OpCode_ESC(27) /* CFF */
	#define OpCode_exch Make_OpCode_ESC(28) /* CFF */
	#define OpCode_index Make_OpCode_ESC(29) /* CFF */
	#define OpCode_roll Make_OpCode_ESC(30) /* CFF */
	#define OpCode_reservedESC31 Make_OpCode_ESC(31)
	#define OpCode_reservedESC32 Make_OpCode_ESC(32)
	#define OpCode_reservedESC33 Make_OpCode_ESC(33)
	#define OpCode_hflex Make_OpCode_ESC(34) /* CFF, CFF2 */
	#define OpCode_flex Make_OpCode_ESC(35) /* CFF, CFF2 */
	#define OpCode_hflex1 Make_OpCode_ESC(36) /* CFF, CFF2 */
	#define OpCode_flex1 Make_OpCode_ESC(37) /* CFF, CFF2 */


	#define OpCode_Invalid 0xFFFFu


	struct number_t
	{
	void set_int (int v) { value = v; }
	int to_int () const { return value; }

	void set_fixed (int32_t v) { value = v / 65536.0; }
	int32_t to_fixed () const { return value * 65536.0; }

	void set_real (double v) { value = v; }
	double to_real () const { return value; }

	bool in_int_range () const
	{ return ((double) (int16_t) to_int () == value); }

	bool operator > (const number_t &n) const { return value > n.to_real (); }
	bool operator < (const number_t &n) const { return n > *this; }
	bool operator >= (const number_t &n) const { return !(*this < n); }
	bool operator <= (const number_t &n) const { return !(*this > n); }

	const number_t &operator += (const number_t &n)
	{
	set_real (to_real () + n.to_real ());

	return *this;
	}

	protected:
	double value = 0.;
	};

	/* byte string */
	struct UnsizedByteStr : UnsizedArrayOf <HBUINT8>
	{
	hb_ubytes_t as_ubytes (unsigned l) const
	{ return hb_ubytes_t ((const unsigned char *) this, l); }

	// encode 2-byte int (Dict/CharString) or 4-byte int (Dict)
	template <typename T, typename V>
	static bool serialize_int (hb_serialize_context_t *c, op_code_t intOp, V value)
	{
	TRACE_SERIALIZE (this);

	HBUINT8 *p = c->allocate_size<HBUINT8> (1);
	if (unlikely (!p)) return_trace (false);
	*p = intOp;

	T *ip = c->allocate_size<T> (T::static_size);
	if (unlikely (!ip)) return_trace (false);
	return_trace (c->check_assign (*ip, value, HB_SERIALIZE_ERROR_INT_OVERFLOW));
	}

	template <typename V>
	static bool serialize_int4 (hb_serialize_context_t *c, V value)
	{ return serialize_int<HBINT32> (c, OpCode_longintdict, value); }

	template <typename V>
	static bool serialize_int2 (hb_serialize_context_t *c, V value)
	{ return serialize_int<HBINT16> (c, OpCode_shortint, value); }

	/* Defining null_size allows a Null object may be created. Should be safe because:
	* A descendent struct Dict uses a Null pointer to indicate a missing table,
	* checked before access.
	*/
	DEFINE_SIZE_MIN(0);
	};

	/* A byte string associated with the current offset and an error condition */
	struct byte_str_ref_t
	{
	byte_str_ref_t ()
	: str () {}

	byte_str_ref_t (const hb_ubytes_t &str_, unsigned int offset_ = 0)
	: str (str_) { set_offset (offset_); }

	void reset (const hb_ubytes_t &str_, unsigned int offset_ = 0)
	{
	str = str_;
	set_offset (offset_);
	}

	const unsigned char& operator [] (int i) {
	if (unlikely ((unsigned int) (get_offset () + i) >= str.length))
	{
	set_error ();
	return Null (unsigned char);
	}
	return str.arrayZ[get_offset () + i];
	}

	unsigned char head_unchecked () const { return str.arrayZ[get_offset ()]; }

	/* Conversion to hb_ubytes_t */
	operator hb_ubytes_t () const { return str.sub_array (get_offset ()); }

	hb_ubytes_t sub_array (unsigned int offset_, unsigned int len_) const
	{ return str.sub_array (offset_, len_); }

	bool avail (unsigned int count=1) const
	{ return get_offset () + count <= str.length; }
	void inc (unsigned int count=1)
	{
	/* Automatically puts us in error if count is out-of-range. */
	set_offset (get_offset () + count);
	}

	/* We (ab)use ubytes backwards_length as a cursor (called offset),
	* as well as to store error condition. */

	unsigned get_offset () const { return str.backwards_length; }
	void set_offset (unsigned offset) { str.backwards_length = offset; }

	void set_error () { str.backwards_length = str.length + 1; }
	bool in_error () const { return str.backwards_length > str.length; }

	unsigned total_size () const { return str.length; }

	protected:
	hb_ubytes_t str;
	};

	/* stack */
	template <typename ELEM, int LIMIT>
	struct cff_stack_t
	{
	ELEM& operator [] (unsigned int i)
	{
	if (unlikely (i >= count))
	{
	set_error ();
	return Crap (ELEM);
	}
	return elements[i];
	}

	void push (const ELEM &v)
	{
	if (likely (count < LIMIT))
	elements[count++] = v;
	else
	set_error ();
	}
	ELEM &push ()
	{
	if (likely (count < LIMIT))
	return elements[count++];
	else
	{
	set_error ();
	return Crap (ELEM);
	}
	}

	ELEM& pop ()
	{
	if (likely (count > 0))
	return elements[--count];
	else
	{
	set_error ();
	return Crap (ELEM);
	}
	}
	void pop (unsigned int n)
	{
	if (likely (count >= n))
	count -= n;
	else
	set_error ();
	}

	const ELEM& peek ()
	{
	if (unlikely (count == 0))
	{
	set_error ();
	return Null (ELEM);
	}
	return elements[count - 1];
	}

	void unpop ()
	{
	if (likely (count < LIMIT))
	count++;
	else
	set_error ();
	}

	void clear () { count = 0; }

	bool in_error () const { return (error); }
	void set_error () { error = true; }

	unsigned int get_count () const { return count; }
	bool is_empty () const { return !count; }

	hb_array_t<const ELEM> sub_array (unsigned start, unsigned length) const
	{ return hb_array_t<const ELEM> (elements).sub_array (start, length); }

	private:
	bool error = false;
	unsigned int count = 0;
	ELEM elements[LIMIT];
	};

	/* argument stack */
	template <typename ARG=number_t>
	struct arg_stack_t : cff_stack_t<ARG, 513>
	{
	void push_int (int v)
	{
	ARG &n = S::push ();
	n.set_int (v);
	}

	void push_fixed (int32_t v)
	{
	ARG &n = S::push ();
	n.set_fixed (v);
	}

	void push_real (double v)
	{
	ARG &n = S::push ();
	n.set_real (v);
	}

	ARG& pop_num () { return this->pop (); }

	int pop_int () { return this->pop ().to_int (); }

	unsigned int pop_uint ()
	{
	int i = pop_int ();
	if (unlikely (i < 0))
	{
	i = 0;
	S::set_error ();
	}
	return (unsigned) i;
	}

	void push_longint_from_substr (byte_str_ref_t& str_ref)
	{
	push_int ((str_ref[0] << 24) \| (str_ref[1] << 16) \| (str_ref[2] << 8) \| (str_ref[3]));
	str_ref.inc (4);
	}

	bool push_fixed_from_substr (byte_str_ref_t& str_ref)
	{
	if (unlikely (!str_ref.avail (4)))
	return false;
	push_fixed ((int32_t)(const HBUINT32)&str_ref[0]);
	str_ref.inc (4);
	return true;
	}

	private:
	typedef cff_stack_t<ARG, 513> S;
	};

	/* an operator prefixed by its operands in a byte string */
	struct op_str_t
	{
	/* This used to have a hb_ubytes_t. Using a pointer and length
	* in a particular order, saves 8 bytes in this struct and more
	* in our parsed_cs_op_t subclass. */

	const unsigned char *ptr = nullptr;

	op_code_t op = OpCode_Invalid;

	uint8_t length = 0;
	};

	/* base of OP_SERIALIZER */
	struct op_serializer_t
	{
	protected:
	bool copy_opstr (hb_serialize_context_t *c, const op_str_t& opstr) const
	{
	TRACE_SERIALIZE (this);

	unsigned char *d = c->allocate_size<unsigned char> (opstr.length);
	if (unlikely (!d)) return_trace (false);
	/* Faster than hb_memcpy for small strings. */
	for (unsigned i = 0; i < opstr.length; i++)
	d[i] = opstr.ptr[i];
	return_trace (true);
	}
	};

	template <typename VAL>
	struct parsed_values_t
	{
	void init ()
	{
	opStart = 0;
	values.init ();
	}
	void fini () { values.fini (); }

	void alloc (unsigned n)
	{
	values.alloc (n, true);
	}

	void add_op (op_code_t op, const byte_str_ref_t& str_ref = byte_str_ref_t (), const VAL &v = VAL ())
	{
	VAL *val = values.push (v);
	val->op = op;
	auto arr = str_ref.sub_array (opStart, str_ref.get_offset () - opStart);
	val->ptr = arr.arrayZ;
	val->length = arr.length;
	opStart = str_ref.get_offset ();
	}

	bool has_op (op_code_t op) const
	{
	for (const auto& v : values)
	if (v.op == op) return true;
	return false;
	}

	unsigned get_count () const { return values.length; }
	const VAL &operator [] (unsigned int i) const { return values[i]; }

	unsigned int opStart;
	hb_vector_t<VAL> values;
	};

	template <typename ARG=number_t>
	struct interp_env_t
	{
	interp_env_t () {}
	interp_env_t (const hb_ubytes_t &str_)
	{
	str_ref.reset (str_);
	}
	bool in_error () const
	{ return str_ref.in_error () \|\| argStack.in_error (); }

	void set_error () { str_ref.set_error (); }

	op_code_t fetch_op ()
	{
	op_code_t op = OpCode_Invalid;
	if (unlikely (!str_ref.avail ()))
	return OpCode_Invalid;
	op = (op_code_t) str_ref.head_unchecked ();
	str_ref.inc ();
	if (op == OpCode_escape) {
	if (unlikely (!str_ref.avail ()))
	return OpCode_Invalid;
	op = Make_OpCode_ESC (str_ref.head_unchecked ());
	str_ref.inc ();
	}
	return op;
	}

	const ARG& eval_arg (unsigned int i) { return argStack[i]; }

	ARG& pop_arg () { return argStack.pop (); }
	void pop_n_args (unsigned int n) { argStack.pop (n); }

	void clear_args () { pop_n_args (argStack.get_count ()); }

	byte_str_ref_t
	str_ref;
	arg_stack_t<ARG>
	argStack;
	};

	using num_interp_env_t = interp_env_t<>;

	template <typename ARG=number_t>
	struct opset_t
	{
	static void process_op (op_code_t op, interp_env_t<ARG>& env)
	{
	switch (op) {
	case OpCode_shortint:
	env.argStack.push_int ((int16_t)((env.str_ref[0] << 8) \| env.str_ref[1]));
	env.str_ref.inc (2);
	break;

	case OpCode_TwoBytePosInt0: case OpCode_TwoBytePosInt1:
	case OpCode_TwoBytePosInt2: case OpCode_TwoBytePosInt3:
	env.argStack.push_int ((int16_t)((op - OpCode_TwoBytePosInt0) * 256 + env.str_ref[0] + 108));
	env.str_ref.inc ();
	break;

	case OpCode_TwoByteNegInt0: case OpCode_TwoByteNegInt1:
	case OpCode_TwoByteNegInt2: case OpCode_TwoByteNegInt3:
	env.argStack.push_int ((-(int16_t)(op - OpCode_TwoByteNegInt0) * 256 - env.str_ref[0] - 108));
	env.str_ref.inc ();
	break;

	default:
	/* 1-byte integer */
	if (likely ((OpCode_OneByteIntFirst <= op) && (op <= OpCode_OneByteIntLast)))
	{
	env.argStack.push_int ((int)op - 139);
	} else {
	/* invalid unknown operator */
	env.clear_args ();
	env.set_error ();
	}
	break;
	}
	}
	};

	template <typename ENV>
	struct interpreter_t
	{
	interpreter_t (ENV& env_) : env (env_) {}
	ENV& env;
	};

	} /* namespace CFF */

	#endif /* HB_CFF_INTERP_COMMON_HH */