/**************************************************************************** * * ttinterp.c * * TrueType bytecode interpreter (body). * * Copyright (C) 1996-2019 by * David Turner, Robert Wilhelm, and Werner Lemberg. * * This file is part of the FreeType project, and may only be used, * modified, and distributed under the terms of the FreeType project * license, LICENSE.TXT. By continuing to use, modify, or distribute * this file you indicate that you have read the license and * understand and accept it fully. * */ /* Greg Hitchcock from Microsoft has helped a lot in resolving unclear */ /* issues; many thanks! */ #include #include FT_INTERNAL_DEBUG_H #include FT_INTERNAL_CALC_H #include FT_TRIGONOMETRY_H #include FT_SYSTEM_H #include FT_DRIVER_H #include FT_MULTIPLE_MASTERS_H #include "ttinterp.h" #include "tterrors.h" #include "ttsubpix.h" #ifdef TT_CONFIG_OPTION_GX_VAR_SUPPORT #include "ttgxvar.h" #endif #ifdef TT_USE_BYTECODE_INTERPRETER /************************************************************************** * * The macro FT_COMPONENT is used in trace mode. It is an implicit * parameter of the FT_TRACE() and FT_ERROR() macros, used to print/log * messages during execution. */ #undef FT_COMPONENT #define FT_COMPONENT ttinterp #define NO_SUBPIXEL_HINTING \ ( ((TT_Driver)FT_FACE_DRIVER( exc->face ))->interpreter_version == \ TT_INTERPRETER_VERSION_35 ) #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY #define SUBPIXEL_HINTING_INFINALITY \ ( ((TT_Driver)FT_FACE_DRIVER( exc->face ))->interpreter_version == \ TT_INTERPRETER_VERSION_38 ) #endif #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL #define SUBPIXEL_HINTING_MINIMAL \ ( ((TT_Driver)FT_FACE_DRIVER( exc->face ))->interpreter_version == \ TT_INTERPRETER_VERSION_40 ) #endif #define PROJECT( v1, v2 ) \ exc->func_project( exc, \ SUB_LONG( (v1)->x, (v2)->x ), \ SUB_LONG( (v1)->y, (v2)->y ) ) #define DUALPROJ( v1, v2 ) \ exc->func_dualproj( exc, \ SUB_LONG( (v1)->x, (v2)->x ), \ SUB_LONG( (v1)->y, (v2)->y ) ) #define FAST_PROJECT( v ) \ exc->func_project( exc, (v)->x, (v)->y ) #define FAST_DUALPROJ( v ) \ exc->func_dualproj( exc, (v)->x, (v)->y ) /************************************************************************** * * Two simple bounds-checking macros. */ #define BOUNDS( x, n ) ( (FT_UInt)(x) >= (FT_UInt)(n) ) #define BOUNDSL( x, n ) ( (FT_ULong)(x) >= (FT_ULong)(n) ) #undef SUCCESS #define SUCCESS 0 #undef FAILURE #define FAILURE 1 /************************************************************************** * * CODERANGE FUNCTIONS * */ /************************************************************************** * * @Function: * TT_Goto_CodeRange * * @Description: * Switches to a new code range (updates the code related elements in * `exec', and `IP'). * * @Input: * range :: * The new execution code range. * * IP :: * The new IP in the new code range. * * @InOut: * exec :: * The target execution context. */ FT_LOCAL_DEF( void ) TT_Goto_CodeRange( TT_ExecContext exec, FT_Int range, FT_Long IP ) { TT_CodeRange* coderange; FT_ASSERT( range >= 1 && range <= 3 ); coderange = &exec->codeRangeTable[range - 1]; FT_ASSERT( coderange->base ); /* NOTE: Because the last instruction of a program may be a CALL */ /* which will return to the first byte *after* the code */ /* range, we test for IP <= Size instead of IP < Size. */ /* */ FT_ASSERT( IP <= coderange->size ); exec->code = coderange->base; exec->codeSize = coderange->size; exec->IP = IP; exec->curRange = range; } /************************************************************************** * * @Function: * TT_Set_CodeRange * * @Description: * Sets a code range. * * @Input: * range :: * The code range index. * * base :: * The new code base. * * length :: * The range size in bytes. * * @InOut: * exec :: * The target execution context. */ FT_LOCAL_DEF( void ) TT_Set_CodeRange( TT_ExecContext exec, FT_Int range, void* base, FT_Long length ) { FT_ASSERT( range >= 1 && range <= 3 ); exec->codeRangeTable[range - 1].base = (FT_Byte*)base; exec->codeRangeTable[range - 1].size = length; } /************************************************************************** * * @Function: * TT_Clear_CodeRange * * @Description: * Clears a code range. * * @Input: * range :: * The code range index. * * @InOut: * exec :: * The target execution context. */ FT_LOCAL_DEF( void ) TT_Clear_CodeRange( TT_ExecContext exec, FT_Int range ) { FT_ASSERT( range >= 1 && range <= 3 ); exec->codeRangeTable[range - 1].base = NULL; exec->codeRangeTable[range - 1].size = 0; } /************************************************************************** * * EXECUTION CONTEXT ROUTINES * */ /************************************************************************** * * @Function: * TT_Done_Context * * @Description: * Destroys a given context. * * @Input: * exec :: * A handle to the target execution context. * * memory :: * A handle to the parent memory object. * * @Note: * Only the glyph loader and debugger should call this function. */ FT_LOCAL_DEF( void ) TT_Done_Context( TT_ExecContext exec ) { FT_Memory memory = exec->memory; /* points zone */ exec->maxPoints = 0; exec->maxContours = 0; /* free stack */ FT_FREE( exec->stack ); exec->stackSize = 0; /* free call stack */ FT_FREE( exec->callStack ); exec->callSize = 0; exec->callTop = 0; /* free glyph code range */ FT_FREE( exec->glyphIns ); exec->glyphSize = 0; exec->size = NULL; exec->face = NULL; FT_FREE( exec ); } /************************************************************************** * * @Function: * Init_Context * * @Description: * Initializes a context object. * * @Input: * memory :: * A handle to the parent memory object. * * @InOut: * exec :: * A handle to the target execution context. * * @Return: * FreeType error code. 0 means success. */ static FT_Error Init_Context( TT_ExecContext exec, FT_Memory memory ) { FT_Error error; FT_TRACE1(( "Init_Context: new object at 0x%08p\n", exec )); exec->memory = memory; exec->callSize = 32; if ( FT_NEW_ARRAY( exec->callStack, exec->callSize ) ) goto Fail_Memory; /* all values in the context are set to 0 already, but this is */ /* here as a remainder */ exec->maxPoints = 0; exec->maxContours = 0; exec->stackSize = 0; exec->glyphSize = 0; exec->stack = NULL; exec->glyphIns = NULL; exec->face = NULL; exec->size = NULL; return FT_Err_Ok; Fail_Memory: FT_ERROR(( "Init_Context: not enough memory for %p\n", exec )); TT_Done_Context( exec ); return error; } /************************************************************************** * * @Function: * Update_Max * * @Description: * Checks the size of a buffer and reallocates it if necessary. * * @Input: * memory :: * A handle to the parent memory object. * * multiplier :: * The size in bytes of each element in the buffer. * * new_max :: * The new capacity (size) of the buffer. * * @InOut: * size :: * The address of the buffer's current size expressed * in elements. * * buff :: * The address of the buffer base pointer. * * @Return: * FreeType error code. 0 means success. */ FT_LOCAL_DEF( FT_Error ) Update_Max( FT_Memory memory, FT_ULong* size, FT_ULong multiplier, void* _pbuff, FT_ULong new_max ) { FT_Error error; void** pbuff = (void**)_pbuff; if ( *size < new_max ) { if ( FT_REALLOC( *pbuff, *size * multiplier, new_max * multiplier ) ) return error; *size = new_max; } return FT_Err_Ok; } /************************************************************************** * * @Function: * TT_Load_Context * * @Description: * Prepare an execution context for glyph hinting. * * @Input: * face :: * A handle to the source face object. * * size :: * A handle to the source size object. * * @InOut: * exec :: * A handle to the target execution context. * * @Return: * FreeType error code. 0 means success. * * @Note: * Only the glyph loader and debugger should call this function. */ FT_LOCAL_DEF( FT_Error ) TT_Load_Context( TT_ExecContext exec, TT_Face face, TT_Size size ) { FT_Int i; FT_ULong tmp; TT_MaxProfile* maxp; FT_Error error; exec->face = face; maxp = &face->max_profile; exec->size = size; if ( size ) { exec->numFDefs = size->num_function_defs; exec->maxFDefs = size->max_function_defs; exec->numIDefs = size->num_instruction_defs; exec->maxIDefs = size->max_instruction_defs; exec->FDefs = size->function_defs; exec->IDefs = size->instruction_defs; exec->pointSize = size->point_size; exec->tt_metrics = size->ttmetrics; exec->metrics = *size->metrics; exec->maxFunc = size->max_func; exec->maxIns = size->max_ins; for ( i = 0; i < TT_MAX_CODE_RANGES; i++ ) exec->codeRangeTable[i] = size->codeRangeTable[i]; /* set graphics state */ exec->GS = size->GS; exec->cvtSize = size->cvt_size; exec->cvt = size->cvt; exec->storeSize = size->storage_size; exec->storage = size->storage; exec->twilight = size->twilight; /* In case of multi-threading it can happen that the old size object */ /* no longer exists, thus we must clear all glyph zone references. */ FT_ZERO( &exec->zp0 ); exec->zp1 = exec->zp0; exec->zp2 = exec->zp0; } /* XXX: We reserve a little more elements on the stack to deal safely */ /* with broken fonts like arialbs, courbs, timesbs, etc. */ tmp = (FT_ULong)exec->stackSize; error = Update_Max( exec->memory, &tmp, sizeof ( FT_F26Dot6 ), (void*)&exec->stack, maxp->maxStackElements + 32 ); exec->stackSize = (FT_Long)tmp; if ( error ) return error; tmp = exec->glyphSize; error = Update_Max( exec->memory, &tmp, sizeof ( FT_Byte ), (void*)&exec->glyphIns, maxp->maxSizeOfInstructions ); exec->glyphSize = (FT_UShort)tmp; if ( error ) return error; exec->pts.n_points = 0; exec->pts.n_contours = 0; exec->zp1 = exec->pts; exec->zp2 = exec->pts; exec->zp0 = exec->pts; exec->instruction_trap = FALSE; return FT_Err_Ok; } /************************************************************************** * * @Function: * TT_Save_Context * * @Description: * Saves the code ranges in a `size' object. * * @Input: * exec :: * A handle to the source execution context. * * @InOut: * size :: * A handle to the target size object. * * @Note: * Only the glyph loader and debugger should call this function. */ FT_LOCAL_DEF( void ) TT_Save_Context( TT_ExecContext exec, TT_Size size ) { FT_Int i; /* XXX: Will probably disappear soon with all the code range */ /* management, which is now rather obsolete. */ /* */ size->num_function_defs = exec->numFDefs; size->num_instruction_defs = exec->numIDefs; size->max_func = exec->maxFunc; size->max_ins = exec->maxIns; for ( i = 0; i < TT_MAX_CODE_RANGES; i++ ) size->codeRangeTable[i] = exec->codeRangeTable[i]; } /************************************************************************** * * @Function: * TT_Run_Context * * @Description: * Executes one or more instructions in the execution context. * * @Input: * exec :: * A handle to the target execution context. * * @Return: * TrueType error code. 0 means success. */ FT_LOCAL_DEF( FT_Error ) TT_Run_Context( TT_ExecContext exec ) { TT_Goto_CodeRange( exec, tt_coderange_glyph, 0 ); exec->zp0 = exec->pts; exec->zp1 = exec->pts; exec->zp2 = exec->pts; exec->GS.gep0 = 1; exec->GS.gep1 = 1; exec->GS.gep2 = 1; exec->GS.projVector.x = 0x4000; exec->GS.projVector.y = 0x0000; exec->GS.freeVector = exec->GS.projVector; exec->GS.dualVector = exec->GS.projVector; exec->GS.round_state = 1; exec->GS.loop = 1; /* some glyphs leave something on the stack. so we clean it */ /* before a new execution. */ exec->top = 0; exec->callTop = 0; return exec->face->interpreter( exec ); } /* The default value for `scan_control' is documented as FALSE in the */ /* TrueType specification. This is confusing since it implies a */ /* Boolean value. However, this is not the case, thus both the */ /* default values of our `scan_type' and `scan_control' fields (which */ /* the documentation's `scan_control' variable is split into) are */ /* zero. */ const TT_GraphicsState tt_default_graphics_state = { 0, 0, 0, { 0x4000, 0 }, { 0x4000, 0 }, { 0x4000, 0 }, 1, 64, 1, TRUE, 68, 0, 0, 9, 3, 0, FALSE, 0, 1, 1, 1 }; /* documentation is in ttinterp.h */ FT_EXPORT_DEF( TT_ExecContext ) TT_New_Context( TT_Driver driver ) { FT_Memory memory; FT_Error error; TT_ExecContext exec = NULL; if ( !driver ) goto Fail; memory = driver->root.root.memory; /* allocate object */ if ( FT_NEW( exec ) ) goto Fail; /* initialize it; in case of error this deallocates `exec' too */ error = Init_Context( exec, memory ); if ( error ) goto Fail; return exec; Fail: return NULL; } /************************************************************************** * * Before an opcode is executed, the interpreter verifies that there are * enough arguments on the stack, with the help of the `Pop_Push_Count' * table. * * For each opcode, the first column gives the number of arguments that * are popped from the stack; the second one gives the number of those * that are pushed in result. * * Opcodes which have a varying number of parameters in the data stream * (NPUSHB, NPUSHW) are handled specially; they have a negative value in * the `opcode_length' table, and the value in `Pop_Push_Count' is set * to zero. * */ #undef PACK #define PACK( x, y ) ( ( x << 4 ) | y ) static const FT_Byte Pop_Push_Count[256] = { /* opcodes are gathered in groups of 16 */ /* please keep the spaces as they are */ /* SVTCA y */ PACK( 0, 0 ), /* SVTCA x */ PACK( 0, 0 ), /* SPvTCA y */ PACK( 0, 0 ), /* SPvTCA x */ PACK( 0, 0 ), /* SFvTCA y */ PACK( 0, 0 ), /* SFvTCA x */ PACK( 0, 0 ), /* SPvTL // */ PACK( 2, 0 ), /* SPvTL + */ PACK( 2, 0 ), /* SFvTL // */ PACK( 2, 0 ), /* SFvTL + */ PACK( 2, 0 ), /* SPvFS */ PACK( 2, 0 ), /* SFvFS */ PACK( 2, 0 ), /* GPv */ PACK( 0, 2 ), /* GFv */ PACK( 0, 2 ), /* SFvTPv */ PACK( 0, 0 ), /* ISECT */ PACK( 5, 0 ), /* SRP0 */ PACK( 1, 0 ), /* SRP1 */ PACK( 1, 0 ), /* SRP2 */ PACK( 1, 0 ), /* SZP0 */ PACK( 1, 0 ), /* SZP1 */ PACK( 1, 0 ), /* SZP2 */ PACK( 1, 0 ), /* SZPS */ PACK( 1, 0 ), /* SLOOP */ PACK( 1, 0 ), /* RTG */ PACK( 0, 0 ), /* RTHG */ PACK( 0, 0 ), /* SMD */ PACK( 1, 0 ), /* ELSE */ PACK( 0, 0 ), /* JMPR */ PACK( 1, 0 ), /* SCvTCi */ PACK( 1, 0 ), /* SSwCi */ PACK( 1, 0 ), /* SSW */ PACK( 1, 0 ), /* DUP */ PACK( 1, 2 ), /* POP */ PACK( 1, 0 ), /* CLEAR */ PACK( 0, 0 ), /* SWAP */ PACK( 2, 2 ), /* DEPTH */ PACK( 0, 1 ), /* CINDEX */ PACK( 1, 1 ), /* MINDEX */ PACK( 1, 0 ), /* AlignPTS */ PACK( 2, 0 ), /* INS_$28 */ PACK( 0, 0 ), /* UTP */ PACK( 1, 0 ), /* LOOPCALL */ PACK( 2, 0 ), /* CALL */ PACK( 1, 0 ), /* FDEF */ PACK( 1, 0 ), /* ENDF */ PACK( 0, 0 ), /* MDAP[0] */ PACK( 1, 0 ), /* MDAP[1] */ PACK( 1, 0 ), /* IUP[0] */ PACK( 0, 0 ), /* IUP[1] */ PACK( 0, 0 ), /* SHP[0] */ PACK( 0, 0 ), /* loops */ /* SHP[1] */ PACK( 0, 0 ), /* loops */ /* SHC[0] */ PACK( 1, 0 ), /* SHC[1] */ PACK( 1, 0 ), /* SHZ[0] */ PACK( 1, 0 ), /* SHZ[1] */ PACK( 1, 0 ), /* SHPIX */ PACK( 1, 0 ), /* loops */ /* IP */ PACK( 0, 0 ), /* loops */ /* MSIRP[0] */ PACK( 2, 0 ), /* MSIRP[1] */ PACK( 2, 0 ), /* AlignRP */ PACK( 0, 0 ), /* loops */ /* RTDG */ PACK( 0, 0 ), /* MIAP[0] */ PACK( 2, 0 ), /* MIAP[1] */ PACK( 2, 0 ), /* NPushB */ PACK( 0, 0 ), /* NPushW */ PACK( 0, 0 ), /* WS */ PACK( 2, 0 ), /* RS */ PACK( 1, 1 ), /* WCvtP */ PACK( 2, 0 ), /* RCvt */ PACK( 1, 1 ), /* GC[0] */ PACK( 1, 1 ), /* GC[1] */ PACK( 1, 1 ), /* SCFS */ PACK( 2, 0 ), /* MD[0] */ PACK( 2, 1 ), /* MD[1] */ PACK( 2, 1 ), /* MPPEM */ PACK( 0, 1 ), /* MPS */ PACK( 0, 1 ), /* FlipON */ PACK( 0, 0 ), /* FlipOFF */ PACK( 0, 0 ), /* DEBUG */ PACK( 1, 0 ), /* LT */ PACK( 2, 1 ), /* LTEQ */ PACK( 2, 1 ), /* GT */ PACK( 2, 1 ), /* GTEQ */ PACK( 2, 1 ), /* EQ */ PACK( 2, 1 ), /* NEQ */ PACK( 2, 1 ), /* ODD */ PACK( 1, 1 ), /* EVEN */ PACK( 1, 1 ), /* IF */ PACK( 1, 0 ), /* EIF */ PACK( 0, 0 ), /* AND */ PACK( 2, 1 ), /* OR */ PACK( 2, 1 ), /* NOT */ PACK( 1, 1 ), /* DeltaP1 */ PACK( 1, 0 ), /* SDB */ PACK( 1, 0 ), /* SDS */ PACK( 1, 0 ), /* ADD */ PACK( 2, 1 ), /* SUB */ PACK( 2, 1 ), /* DIV */ PACK( 2, 1 ), /* MUL */ PACK( 2, 1 ), /* ABS */ PACK( 1, 1 ), /* NEG */ PACK( 1, 1 ), /* FLOOR */ PACK( 1, 1 ), /* CEILING */ PACK( 1, 1 ), /* ROUND[0] */ PACK( 1, 1 ), /* ROUND[1] */ PACK( 1, 1 ), /* ROUND[2] */ PACK( 1, 1 ), /* ROUND[3] */ PACK( 1, 1 ), /* NROUND[0] */ PACK( 1, 1 ), /* NROUND[1] */ PACK( 1, 1 ), /* NROUND[2] */ PACK( 1, 1 ), /* NROUND[3] */ PACK( 1, 1 ), /* WCvtF */ PACK( 2, 0 ), /* DeltaP2 */ PACK( 1, 0 ), /* DeltaP3 */ PACK( 1, 0 ), /* DeltaCn[0] */ PACK( 1, 0 ), /* DeltaCn[1] */ PACK( 1, 0 ), /* DeltaCn[2] */ PACK( 1, 0 ), /* SROUND */ PACK( 1, 0 ), /* S45Round */ PACK( 1, 0 ), /* JROT */ PACK( 2, 0 ), /* JROF */ PACK( 2, 0 ), /* ROFF */ PACK( 0, 0 ), /* INS_$7B */ PACK( 0, 0 ), /* RUTG */ PACK( 0, 0 ), /* RDTG */ PACK( 0, 0 ), /* SANGW */ PACK( 1, 0 ), /* AA */ PACK( 1, 0 ), /* FlipPT */ PACK( 0, 0 ), /* loops */ /* FlipRgON */ PACK( 2, 0 ), /* FlipRgOFF */ PACK( 2, 0 ), /* INS_$83 */ PACK( 0, 0 ), /* INS_$84 */ PACK( 0, 0 ), /* ScanCTRL */ PACK( 1, 0 ), /* SDPvTL[0] */ PACK( 2, 0 ), /* SDPvTL[1] */ PACK( 2, 0 ), /* GetINFO */ PACK( 1, 1 ), /* IDEF */ PACK( 1, 0 ), /* ROLL */ PACK( 3, 3 ), /* MAX */ PACK( 2, 1 ), /* MIN */ PACK( 2, 1 ), /* ScanTYPE */ PACK( 1, 0 ), /* InstCTRL */ PACK( 2, 0 ), /* INS_$8F */ PACK( 0, 0 ), /* INS_$90 */ PACK( 0, 0 ), /* GETVAR */ PACK( 0, 0 ), /* will be handled specially */ /* GETDATA */ PACK( 0, 1 ), /* INS_$93 */ PACK( 0, 0 ), /* INS_$94 */ PACK( 0, 0 ), /* INS_$95 */ PACK( 0, 0 ), /* INS_$96 */ PACK( 0, 0 ), /* INS_$97 */ PACK( 0, 0 ), /* INS_$98 */ PACK( 0, 0 ), /* INS_$99 */ PACK( 0, 0 ), /* INS_$9A */ PACK( 0, 0 ), /* INS_$9B */ PACK( 0, 0 ), /* INS_$9C */ PACK( 0, 0 ), /* INS_$9D */ PACK( 0, 0 ), /* INS_$9E */ PACK( 0, 0 ), /* INS_$9F */ PACK( 0, 0 ), /* INS_$A0 */ PACK( 0, 0 ), /* INS_$A1 */ PACK( 0, 0 ), /* INS_$A2 */ PACK( 0, 0 ), /* INS_$A3 */ PACK( 0, 0 ), /* INS_$A4 */ PACK( 0, 0 ), /* INS_$A5 */ PACK( 0, 0 ), /* INS_$A6 */ PACK( 0, 0 ), /* INS_$A7 */ PACK( 0, 0 ), /* INS_$A8 */ PACK( 0, 0 ), /* INS_$A9 */ PACK( 0, 0 ), /* INS_$AA */ PACK( 0, 0 ), /* INS_$AB */ PACK( 0, 0 ), /* INS_$AC */ PACK( 0, 0 ), /* INS_$AD */ PACK( 0, 0 ), /* INS_$AE */ PACK( 0, 0 ), /* INS_$AF */ PACK( 0, 0 ), /* PushB[0] */ PACK( 0, 1 ), /* PushB[1] */ PACK( 0, 2 ), /* PushB[2] */ PACK( 0, 3 ), /* PushB[3] */ PACK( 0, 4 ), /* PushB[4] */ PACK( 0, 5 ), /* PushB[5] */ PACK( 0, 6 ), /* PushB[6] */ PACK( 0, 7 ), /* PushB[7] */ PACK( 0, 8 ), /* PushW[0] */ PACK( 0, 1 ), /* PushW[1] */ PACK( 0, 2 ), /* PushW[2] */ PACK( 0, 3 ), /* PushW[3] */ PACK( 0, 4 ), /* PushW[4] */ PACK( 0, 5 ), /* PushW[5] */ PACK( 0, 6 ), /* PushW[6] */ PACK( 0, 7 ), /* PushW[7] */ PACK( 0, 8 ), /* MDRP[00] */ PACK( 1, 0 ), /* MDRP[01] */ PACK( 1, 0 ), /* MDRP[02] */ PACK( 1, 0 ), /* MDRP[03] */ PACK( 1, 0 ), /* MDRP[04] */ PACK( 1, 0 ), /* MDRP[05] */ PACK( 1, 0 ), /* MDRP[06] */ PACK( 1, 0 ), /* MDRP[07] */ PACK( 1, 0 ), /* MDRP[08] */ PACK( 1, 0 ), /* MDRP[09] */ PACK( 1, 0 ), /* MDRP[10] */ PACK( 1, 0 ), /* MDRP[11] */ PACK( 1, 0 ), /* MDRP[12] */ PACK( 1, 0 ), /* MDRP[13] */ PACK( 1, 0 ), /* MDRP[14] */ PACK( 1, 0 ), /* MDRP[15] */ PACK( 1, 0 ), /* MDRP[16] */ PACK( 1, 0 ), /* MDRP[17] */ PACK( 1, 0 ), /* MDRP[18] */ PACK( 1, 0 ), /* MDRP[19] */ PACK( 1, 0 ), /* MDRP[20] */ PACK( 1, 0 ), /* MDRP[21] */ PACK( 1, 0 ), /* MDRP[22] */ PACK( 1, 0 ), /* MDRP[23] */ PACK( 1, 0 ), /* MDRP[24] */ PACK( 1, 0 ), /* MDRP[25] */ PACK( 1, 0 ), /* MDRP[26] */ PACK( 1, 0 ), /* MDRP[27] */ PACK( 1, 0 ), /* MDRP[28] */ PACK( 1, 0 ), /* MDRP[29] */ PACK( 1, 0 ), /* MDRP[30] */ PACK( 1, 0 ), /* MDRP[31] */ PACK( 1, 0 ), /* MIRP[00] */ PACK( 2, 0 ), /* MIRP[01] */ PACK( 2, 0 ), /* MIRP[02] */ PACK( 2, 0 ), /* MIRP[03] */ PACK( 2, 0 ), /* MIRP[04] */ PACK( 2, 0 ), /* MIRP[05] */ PACK( 2, 0 ), /* MIRP[06] */ PACK( 2, 0 ), /* MIRP[07] */ PACK( 2, 0 ), /* MIRP[08] */ PACK( 2, 0 ), /* MIRP[09] */ PACK( 2, 0 ), /* MIRP[10] */ PACK( 2, 0 ), /* MIRP[11] */ PACK( 2, 0 ), /* MIRP[12] */ PACK( 2, 0 ), /* MIRP[13] */ PACK( 2, 0 ), /* MIRP[14] */ PACK( 2, 0 ), /* MIRP[15] */ PACK( 2, 0 ), /* MIRP[16] */ PACK( 2, 0 ), /* MIRP[17] */ PACK( 2, 0 ), /* MIRP[18] */ PACK( 2, 0 ), /* MIRP[19] */ PACK( 2, 0 ), /* MIRP[20] */ PACK( 2, 0 ), /* MIRP[21] */ PACK( 2, 0 ), /* MIRP[22] */ PACK( 2, 0 ), /* MIRP[23] */ PACK( 2, 0 ), /* MIRP[24] */ PACK( 2, 0 ), /* MIRP[25] */ PACK( 2, 0 ), /* MIRP[26] */ PACK( 2, 0 ), /* MIRP[27] */ PACK( 2, 0 ), /* MIRP[28] */ PACK( 2, 0 ), /* MIRP[29] */ PACK( 2, 0 ), /* MIRP[30] */ PACK( 2, 0 ), /* MIRP[31] */ PACK( 2, 0 ) }; #ifdef FT_DEBUG_LEVEL_TRACE /* the first hex digit gives the length of the opcode name; the space */ /* after the digit is here just to increase readability of the source */ /* code */ static const char* const opcode_name[256] = { "7 SVTCA y", "7 SVTCA x", "8 SPvTCA y", "8 SPvTCA x", "8 SFvTCA y", "8 SFvTCA x", "8 SPvTL ||", "7 SPvTL +", "8 SFvTL ||", "7 SFvTL +", "5 SPvFS", "5 SFvFS", "3 GPv", "3 GFv", "6 SFvTPv", "5 ISECT", "4 SRP0", "4 SRP1", "4 SRP2", "4 SZP0", "4 SZP1", "4 SZP2", "4 SZPS", "5 SLOOP", "3 RTG", "4 RTHG", "3 SMD", "4 ELSE", "4 JMPR", "6 SCvTCi", "5 SSwCi", "3 SSW", "3 DUP", "3 POP", "5 CLEAR", "4 SWAP", "5 DEPTH", "6 CINDEX", "6 MINDEX", "8 AlignPTS", "7 INS_$28", "3 UTP", "8 LOOPCALL", "4 CALL", "4 FDEF", "4 ENDF", "7 MDAP[0]", "7 MDAP[1]", "6 IUP[0]", "6 IUP[1]", "6 SHP[0]", "6 SHP[1]", "6 SHC[0]", "6 SHC[1]", "6 SHZ[0]", "6 SHZ[1]", "5 SHPIX", "2 IP", "8 MSIRP[0]", "8 MSIRP[1]", "7 AlignRP", "4 RTDG", "7 MIAP[0]", "7 MIAP[1]", "6 NPushB", "6 NPushW", "2 WS", "2 RS", "5 WCvtP", "4 RCvt", "5 GC[0]", "5 GC[1]", "4 SCFS", "5 MD[0]", "5 MD[1]", "5 MPPEM", "3 MPS", "6 FlipON", "7 FlipOFF", "5 DEBUG", "2 LT", "4 LTEQ", "2 GT", "4 GTEQ", "2 EQ", "3 NEQ", "3 ODD", "4 EVEN", "2 IF", "3 EIF", "3 AND", "2 OR", "3 NOT", "7 DeltaP1", "3 SDB", "3 SDS", "3 ADD", "3 SUB", "3 DIV", "3 MUL", "3 ABS", "3 NEG", "5 FLOOR", "7 CEILING", "8 ROUND[0]", "8 ROUND[1]", "8 ROUND[2]", "8 ROUND[3]", "9 NROUND[0]", "9 NROUND[1]", "9 NROUND[2]", "9 NROUND[3]", "5 WCvtF", "7 DeltaP2", "7 DeltaP3", "A DeltaCn[0]", "A DeltaCn[1]", "A DeltaCn[2]", "6 SROUND", "8 S45Round", "4 JROT", "4 JROF", "4 ROFF", "7 INS_$7B", "4 RUTG", "4 RDTG", "5 SANGW", "2 AA", "6 FlipPT", "8 FlipRgON", "9 FlipRgOFF", "7 INS_$83", "7 INS_$84", "8 ScanCTRL", "9 SDPvTL[0]", "9 SDPvTL[1]", "7 GetINFO", "4 IDEF", "4 ROLL", "3 MAX", "3 MIN", "8 ScanTYPE", "8 InstCTRL", "7 INS_$8F", "7 INS_$90", #ifdef TT_CONFIG_OPTION_GX_VAR_SUPPORT "6 GETVAR", "7 GETDATA", #else "7 INS_$91", "7 INS_$92", #endif "7 INS_$93", "7 INS_$94", "7 INS_$95", "7 INS_$96", "7 INS_$97", "7 INS_$98", "7 INS_$99", "7 INS_$9A", "7 INS_$9B", "7 INS_$9C", "7 INS_$9D", "7 INS_$9E", "7 INS_$9F", "7 INS_$A0", "7 INS_$A1", "7 INS_$A2", "7 INS_$A3", "7 INS_$A4", "7 INS_$A5", "7 INS_$A6", "7 INS_$A7", "7 INS_$A8", "7 INS_$A9", "7 INS_$AA", "7 INS_$AB", "7 INS_$AC", "7 INS_$AD", "7 INS_$AE", "7 INS_$AF", "8 PushB[0]", "8 PushB[1]", "8 PushB[2]", "8 PushB[3]", "8 PushB[4]", "8 PushB[5]", "8 PushB[6]", "8 PushB[7]", "8 PushW[0]", "8 PushW[1]", "8 PushW[2]", "8 PushW[3]", "8 PushW[4]", "8 PushW[5]", "8 PushW[6]", "8 PushW[7]", "7 MDRP[G]", "7 MDRP[B]", "7 MDRP[W]", "7 MDRP[?]", "8 MDRP[rG]", "8 MDRP[rB]", "8 MDRP[rW]", "8 MDRP[r?]", "8 MDRP[mG]", "8 MDRP[mB]", "8 MDRP[mW]", "8 MDRP[m?]", "9 MDRP[mrG]", "9 MDRP[mrB]", "9 MDRP[mrW]", "9 MDRP[mr?]", "8 MDRP[pG]", "8 MDRP[pB]", "8 MDRP[pW]", "8 MDRP[p?]", "9 MDRP[prG]", "9 MDRP[prB]", "9 MDRP[prW]", "9 MDRP[pr?]", "9 MDRP[pmG]", "9 MDRP[pmB]", "9 MDRP[pmW]", "9 MDRP[pm?]", "A MDRP[pmrG]", "A MDRP[pmrB]", "A MDRP[pmrW]", "A MDRP[pmr?]", "7 MIRP[G]", "7 MIRP[B]", "7 MIRP[W]", "7 MIRP[?]", "8 MIRP[rG]", "8 MIRP[rB]", "8 MIRP[rW]", "8 MIRP[r?]", "8 MIRP[mG]", "8 MIRP[mB]", "8 MIRP[mW]", "8 MIRP[m?]", "9 MIRP[mrG]", "9 MIRP[mrB]", "9 MIRP[mrW]", "9 MIRP[mr?]", "8 MIRP[pG]", "8 MIRP[pB]", "8 MIRP[pW]", "8 MIRP[p?]", "9 MIRP[prG]", "9 MIRP[prB]", "9 MIRP[prW]", "9 MIRP[pr?]", "9 MIRP[pmG]", "9 MIRP[pmB]", "9 MIRP[pmW]", "9 MIRP[pm?]", "A MIRP[pmrG]", "A MIRP[pmrB]", "A MIRP[pmrW]", "A MIRP[pmr?]" }; #endif /* FT_DEBUG_LEVEL_TRACE */ static const FT_Char opcode_length[256] = { 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, -1,-2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 3, 4, 5, 6, 7, 8, 9, 3, 5, 7, 9, 11,13,15,17, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }; #undef PACK #ifndef FT_CONFIG_OPTION_NO_ASSEMBLER #if defined( __arm__ ) && \ ( defined( __thumb2__ ) || !defined( __thumb__ ) ) #define TT_MulFix14 TT_MulFix14_arm static FT_Int32 TT_MulFix14_arm( FT_Int32 a, FT_Int b ) { FT_Int32 t, t2; #if defined( __CC_ARM ) || defined( __ARMCC__ ) __asm { smull t2, t, b, a /* (lo=t2,hi=t) = a*b */ mov a, t, asr #31 /* a = (hi >> 31) */ add a, a, #0x2000 /* a += 0x2000 */ adds t2, t2, a /* t2 += a */ adc t, t, #0 /* t += carry */ mov a, t2, lsr #14 /* a = t2 >> 14 */ orr a, a, t, lsl #18 /* a |= t << 18 */ } #elif defined( __GNUC__ ) __asm__ __volatile__ ( "smull %1, %2, %4, %3\n\t" /* (lo=%1,hi=%2) = a*b */ "mov %0, %2, asr #31\n\t" /* %0 = (hi >> 31) */ #if defined( __clang__ ) && defined( __thumb2__ ) "add.w %0, %0, #0x2000\n\t" /* %0 += 0x2000 */ #else "add %0, %0, #0x2000\n\t" /* %0 += 0x2000 */ #endif "adds %1, %1, %0\n\t" /* %1 += %0 */ "adc %2, %2, #0\n\t" /* %2 += carry */ "mov %0, %1, lsr #14\n\t" /* %0 = %1 >> 16 */ "orr %0, %0, %2, lsl #18\n\t" /* %0 |= %2 << 16 */ : "=r"(a), "=&r"(t2), "=&r"(t) : "r"(a), "r"(b) : "cc" ); #endif return a; } #endif /* __arm__ && ( __thumb2__ || !__thumb__ ) */ #endif /* !FT_CONFIG_OPTION_NO_ASSEMBLER */ #if defined( __GNUC__ ) && \ ( defined( __i386__ ) || defined( __x86_64__ ) ) #define TT_MulFix14 TT_MulFix14_long_long /* Temporarily disable the warning that C90 doesn't support `long long'. */ #if ( __GNUC__ * 100 + __GNUC_MINOR__ ) >= 406 #pragma GCC diagnostic push #endif #pragma GCC diagnostic ignored "-Wlong-long" /* This is declared `noinline' because inlining the function results */ /* in slower code. The `pure' attribute indicates that the result */ /* only depends on the parameters. */ static __attribute__(( noinline )) __attribute__(( pure )) FT_Int32 TT_MulFix14_long_long( FT_Int32 a, FT_Int b ) { long long ret = (long long)a * b; /* The following line assumes that right shifting of signed values */ /* will actually preserve the sign bit. The exact behaviour is */ /* undefined, but this is true on x86 and x86_64. */ long long tmp = ret >> 63; ret += 0x2000 + tmp; return (FT_Int32)( ret >> 14 ); } #if ( __GNUC__ * 100 + __GNUC_MINOR__ ) >= 406 #pragma GCC diagnostic pop #endif #endif /* __GNUC__ && ( __i386__ || __x86_64__ ) */ #ifndef TT_MulFix14 /* Compute (a*b)/2^14 with maximum accuracy and rounding. */ /* This is optimized to be faster than calling FT_MulFix() */ /* for platforms where sizeof(int) == 2. */ static FT_Int32 TT_MulFix14( FT_Int32 a, FT_Int b ) { FT_Int32 sign; FT_UInt32 ah, al, mid, lo, hi; sign = a ^ b; if ( a < 0 ) a = -a; if ( b < 0 ) b = -b; ah = (FT_UInt32)( ( a >> 16 ) & 0xFFFFU ); al = (FT_UInt32)( a & 0xFFFFU ); lo = al * b; mid = ah * b; hi = mid >> 16; mid = ( mid << 16 ) + ( 1 << 13 ); /* rounding */ lo += mid; if ( lo < mid ) hi += 1; mid = ( lo >> 14 ) | ( hi << 18 ); return sign >= 0 ? (FT_Int32)mid : -(FT_Int32)mid; } #endif /* !TT_MulFix14 */ #if defined( __GNUC__ ) && \ ( defined( __i386__ ) || \ defined( __x86_64__ ) || \ defined( __arm__ ) ) #define TT_DotFix14 TT_DotFix14_long_long #if ( __GNUC__ * 100 + __GNUC_MINOR__ ) >= 406 #pragma GCC diagnostic push #endif #pragma GCC diagnostic ignored "-Wlong-long" static __attribute__(( pure )) FT_Int32 TT_DotFix14_long_long( FT_Int32 ax, FT_Int32 ay, FT_Int bx, FT_Int by ) { /* Temporarily disable the warning that C90 doesn't support */ /* `long long'. */ long long temp1 = (long long)ax * bx; long long temp2 = (long long)ay * by; temp1 += temp2; temp2 = temp1 >> 63; temp1 += 0x2000 + temp2; return (FT_Int32)( temp1 >> 14 ); } #if ( __GNUC__ * 100 + __GNUC_MINOR__ ) >= 406 #pragma GCC diagnostic pop #endif #endif /* __GNUC__ && (__arm__ || __i386__ || __x86_64__) */ #ifndef TT_DotFix14 /* compute (ax*bx+ay*by)/2^14 with maximum accuracy and rounding */ static FT_Int32 TT_DotFix14( FT_Int32 ax, FT_Int32 ay, FT_Int bx, FT_Int by ) { FT_Int32 m, s, hi1, hi2, hi; FT_UInt32 l, lo1, lo2, lo; /* compute ax*bx as 64-bit value */ l = (FT_UInt32)( ( ax & 0xFFFFU ) * bx ); m = ( ax >> 16 ) * bx; lo1 = l + ( (FT_UInt32)m << 16 ); hi1 = ( m >> 16 ) + ( (FT_Int32)l >> 31 ) + ( lo1 < l ); /* compute ay*by as 64-bit value */ l = (FT_UInt32)( ( ay & 0xFFFFU ) * by ); m = ( ay >> 16 ) * by; lo2 = l + ( (FT_UInt32)m << 16 ); hi2 = ( m >> 16 ) + ( (FT_Int32)l >> 31 ) + ( lo2 < l ); /* add them */ lo = lo1 + lo2; hi = hi1 + hi2 + ( lo < lo1 ); /* divide the result by 2^14 with rounding */ s = hi >> 31; l = lo + (FT_UInt32)s; hi += s + ( l < lo ); lo = l; l = lo + 0x2000U; hi += ( l < lo ); return (FT_Int32)( ( (FT_UInt32)hi << 18 ) | ( l >> 14 ) ); } #endif /* TT_DotFix14 */ /************************************************************************** * * @Function: * Current_Ratio * * @Description: * Returns the current aspect ratio scaling factor depending on the * projection vector's state and device resolutions. * * @Return: * The aspect ratio in 16.16 format, always <= 1.0 . */ static FT_Long Current_Ratio( TT_ExecContext exc ) { if ( !exc->tt_metrics.ratio ) { if ( exc->GS.projVector.y == 0 ) exc->tt_metrics.ratio = exc->tt_metrics.x_ratio; else if ( exc->GS.projVector.x == 0 ) exc->tt_metrics.ratio = exc->tt_metrics.y_ratio; else { FT_F26Dot6 x, y; x = TT_MulFix14( exc->tt_metrics.x_ratio, exc->GS.projVector.x ); y = TT_MulFix14( exc->tt_metrics.y_ratio, exc->GS.projVector.y ); exc->tt_metrics.ratio = FT_Hypot( x, y ); } } return exc->tt_metrics.ratio; } FT_CALLBACK_DEF( FT_Long ) Current_Ppem( TT_ExecContext exc ) { return exc->tt_metrics.ppem; } FT_CALLBACK_DEF( FT_Long ) Current_Ppem_Stretched( TT_ExecContext exc ) { return FT_MulFix( exc->tt_metrics.ppem, Current_Ratio( exc ) ); } /************************************************************************** * * Functions related to the control value table (CVT). * */ FT_CALLBACK_DEF( FT_F26Dot6 ) Read_CVT( TT_ExecContext exc, FT_ULong idx ) { return exc->cvt[idx]; } FT_CALLBACK_DEF( FT_F26Dot6 ) Read_CVT_Stretched( TT_ExecContext exc, FT_ULong idx ) { return FT_MulFix( exc->cvt[idx], Current_Ratio( exc ) ); } FT_CALLBACK_DEF( void ) Write_CVT( TT_ExecContext exc, FT_ULong idx, FT_F26Dot6 value ) { exc->cvt[idx] = value; } FT_CALLBACK_DEF( void ) Write_CVT_Stretched( TT_ExecContext exc, FT_ULong idx, FT_F26Dot6 value ) { exc->cvt[idx] = FT_DivFix( value, Current_Ratio( exc ) ); } FT_CALLBACK_DEF( void ) Move_CVT( TT_ExecContext exc, FT_ULong idx, FT_F26Dot6 value ) { exc->cvt[idx] = ADD_LONG( exc->cvt[idx], value ); } FT_CALLBACK_DEF( void ) Move_CVT_Stretched( TT_ExecContext exc, FT_ULong idx, FT_F26Dot6 value ) { exc->cvt[idx] = ADD_LONG( exc->cvt[idx], FT_DivFix( value, Current_Ratio( exc ) ) ); } /************************************************************************** * * @Function: * GetShortIns * * @Description: * Returns a short integer taken from the instruction stream at * address IP. * * @Return: * Short read at code[IP]. * * @Note: * This one could become a macro. */ static FT_Short GetShortIns( TT_ExecContext exc ) { /* Reading a byte stream so there is no endianness (DaveP) */ exc->IP += 2; return (FT_Short)( ( exc->code[exc->IP - 2] << 8 ) + exc->code[exc->IP - 1] ); } /************************************************************************** * * @Function: * Ins_Goto_CodeRange * * @Description: * Goes to a certain code range in the instruction stream. * * @Input: * aRange :: * The index of the code range. * * aIP :: * The new IP address in the code range. * * @Return: * SUCCESS or FAILURE. */ static FT_Bool Ins_Goto_CodeRange( TT_ExecContext exc, FT_Int aRange, FT_Long aIP ) { TT_CodeRange* range; if ( aRange < 1 || aRange > 3 ) { exc->error = FT_THROW( Bad_Argument ); return FAILURE; } range = &exc->codeRangeTable[aRange - 1]; if ( !range->base ) /* invalid coderange */ { exc->error = FT_THROW( Invalid_CodeRange ); return FAILURE; } /* NOTE: Because the last instruction of a program may be a CALL */ /* which will return to the first byte *after* the code */ /* range, we test for aIP <= Size, instead of aIP < Size. */ if ( aIP > range->size ) { exc->error = FT_THROW( Code_Overflow ); return FAILURE; } exc->code = range->base; exc->codeSize = range->size; exc->IP = aIP; exc->curRange = aRange; return SUCCESS; } /************************************************************************** * * @Function: * Direct_Move * * @Description: * Moves a point by a given distance along the freedom vector. The * point will be `touched'. * * @Input: * point :: * The index of the point to move. * * distance :: * The distance to apply. * * @InOut: * zone :: * The affected glyph zone. * * @Note: * See `ttinterp.h' for details on backward compatibility mode. * `Touches' the point. */ static void Direct_Move( TT_ExecContext exc, TT_GlyphZone zone, FT_UShort point, FT_F26Dot6 distance ) { FT_F26Dot6 v; v = exc->GS.freeVector.x; if ( v != 0 ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && ( !exc->ignore_x_mode || ( exc->sph_tweak_flags & SPH_TWEAK_ALLOW_X_DMOVE ) ) ) zone->cur[point].x = ADD_LONG( zone->cur[point].x, FT_MulDiv( distance, v, exc->F_dot_P ) ); else #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* Exception to the post-IUP curfew: Allow the x component of */ /* diagonal moves, but only post-IUP. DejaVu tries to adjust */ /* diagonal stems like on `Z' and `z' post-IUP. */ if ( SUBPIXEL_HINTING_MINIMAL && !exc->backward_compatibility ) zone->cur[point].x = ADD_LONG( zone->cur[point].x, FT_MulDiv( distance, v, exc->F_dot_P ) ); else #endif if ( NO_SUBPIXEL_HINTING ) zone->cur[point].x = ADD_LONG( zone->cur[point].x, FT_MulDiv( distance, v, exc->F_dot_P ) ); zone->tags[point] |= FT_CURVE_TAG_TOUCH_X; } v = exc->GS.freeVector.y; if ( v != 0 ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL if ( !( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility && exc->iupx_called && exc->iupy_called ) ) #endif zone->cur[point].y = ADD_LONG( zone->cur[point].y, FT_MulDiv( distance, v, exc->F_dot_P ) ); zone->tags[point] |= FT_CURVE_TAG_TOUCH_Y; } } /************************************************************************** * * @Function: * Direct_Move_Orig * * @Description: * Moves the *original* position of a point by a given distance along * the freedom vector. Obviously, the point will not be `touched'. * * @Input: * point :: * The index of the point to move. * * distance :: * The distance to apply. * * @InOut: * zone :: * The affected glyph zone. */ static void Direct_Move_Orig( TT_ExecContext exc, TT_GlyphZone zone, FT_UShort point, FT_F26Dot6 distance ) { FT_F26Dot6 v; v = exc->GS.freeVector.x; if ( v != 0 ) zone->org[point].x = ADD_LONG( zone->org[point].x, FT_MulDiv( distance, v, exc->F_dot_P ) ); v = exc->GS.freeVector.y; if ( v != 0 ) zone->org[point].y = ADD_LONG( zone->org[point].y, FT_MulDiv( distance, v, exc->F_dot_P ) ); } /************************************************************************** * * Special versions of Direct_Move() * * The following versions are used whenever both vectors are both * along one of the coordinate unit vectors, i.e. in 90% of the cases. * See `ttinterp.h' for details on backward compatibility mode. * */ static void Direct_Move_X( TT_ExecContext exc, TT_GlyphZone zone, FT_UShort point, FT_F26Dot6 distance ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && !exc->ignore_x_mode ) zone->cur[point].x = ADD_LONG( zone->cur[point].x, distance ); else #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL if ( SUBPIXEL_HINTING_MINIMAL && !exc->backward_compatibility ) zone->cur[point].x = ADD_LONG( zone->cur[point].x, distance ); else #endif if ( NO_SUBPIXEL_HINTING ) zone->cur[point].x = ADD_LONG( zone->cur[point].x, distance ); zone->tags[point] |= FT_CURVE_TAG_TOUCH_X; } static void Direct_Move_Y( TT_ExecContext exc, TT_GlyphZone zone, FT_UShort point, FT_F26Dot6 distance ) { FT_UNUSED( exc ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL if ( !( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility && exc->iupx_called && exc->iupy_called ) ) #endif zone->cur[point].y = ADD_LONG( zone->cur[point].y, distance ); zone->tags[point] |= FT_CURVE_TAG_TOUCH_Y; } /************************************************************************** * * Special versions of Direct_Move_Orig() * * The following versions are used whenever both vectors are both * along one of the coordinate unit vectors, i.e. in 90% of the cases. * */ static void Direct_Move_Orig_X( TT_ExecContext exc, TT_GlyphZone zone, FT_UShort point, FT_F26Dot6 distance ) { FT_UNUSED( exc ); zone->org[point].x = ADD_LONG( zone->org[point].x, distance ); } static void Direct_Move_Orig_Y( TT_ExecContext exc, TT_GlyphZone zone, FT_UShort point, FT_F26Dot6 distance ) { FT_UNUSED( exc ); zone->org[point].y = ADD_LONG( zone->org[point].y, distance ); } /************************************************************************** * * @Function: * Round_None * * @Description: * Does not round, but adds engine compensation. * * @Input: * distance :: * The distance (not) to round. * * compensation :: * The engine compensation. * * @Return: * The compensated distance. * * @Note: * The TrueType specification says very few about the relationship * between rounding and engine compensation. However, it seems from * the description of super round that we should add the compensation * before rounding. */ static FT_F26Dot6 Round_None( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; FT_UNUSED( exc ); if ( distance >= 0 ) { val = ADD_LONG( distance, compensation ); if ( val < 0 ) val = 0; } else { val = SUB_LONG( distance, compensation ); if ( val > 0 ) val = 0; } return val; } /************************************************************************** * * @Function: * Round_To_Grid * * @Description: * Rounds value to grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. */ static FT_F26Dot6 Round_To_Grid( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; FT_UNUSED( exc ); if ( distance >= 0 ) { val = FT_PIX_ROUND_LONG( ADD_LONG( distance, compensation ) ); if ( val < 0 ) val = 0; } else { val = NEG_LONG( FT_PIX_ROUND_LONG( SUB_LONG( compensation, distance ) ) ); if ( val > 0 ) val = 0; } return val; } /************************************************************************** * * @Function: * Round_To_Half_Grid * * @Description: * Rounds value to half grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. */ static FT_F26Dot6 Round_To_Half_Grid( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; FT_UNUSED( exc ); if ( distance >= 0 ) { val = ADD_LONG( FT_PIX_FLOOR( ADD_LONG( distance, compensation ) ), 32 ); if ( val < 0 ) val = 32; } else { val = NEG_LONG( ADD_LONG( FT_PIX_FLOOR( SUB_LONG( compensation, distance ) ), 32 ) ); if ( val > 0 ) val = -32; } return val; } /************************************************************************** * * @Function: * Round_Down_To_Grid * * @Description: * Rounds value down to grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. */ static FT_F26Dot6 Round_Down_To_Grid( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; FT_UNUSED( exc ); if ( distance >= 0 ) { val = FT_PIX_FLOOR( ADD_LONG( distance, compensation ) ); if ( val < 0 ) val = 0; } else { val = NEG_LONG( FT_PIX_FLOOR( SUB_LONG( compensation, distance ) ) ); if ( val > 0 ) val = 0; } return val; } /************************************************************************** * * @Function: * Round_Up_To_Grid * * @Description: * Rounds value up to grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. */ static FT_F26Dot6 Round_Up_To_Grid( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; FT_UNUSED( exc ); if ( distance >= 0 ) { val = FT_PIX_CEIL_LONG( ADD_LONG( distance, compensation ) ); if ( val < 0 ) val = 0; } else { val = NEG_LONG( FT_PIX_CEIL_LONG( SUB_LONG( compensation, distance ) ) ); if ( val > 0 ) val = 0; } return val; } /************************************************************************** * * @Function: * Round_To_Double_Grid * * @Description: * Rounds value to double grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. */ static FT_F26Dot6 Round_To_Double_Grid( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; FT_UNUSED( exc ); if ( distance >= 0 ) { val = FT_PAD_ROUND_LONG( ADD_LONG( distance, compensation ), 32 ); if ( val < 0 ) val = 0; } else { val = NEG_LONG( FT_PAD_ROUND_LONG( SUB_LONG( compensation, distance ), 32 ) ); if ( val > 0 ) val = 0; } return val; } /************************************************************************** * * @Function: * Round_Super * * @Description: * Super-rounds value to grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. * * @Note: * The TrueType specification says very little about the relationship * between rounding and engine compensation. However, it seems from * the description of super round that we should add the compensation * before rounding. */ static FT_F26Dot6 Round_Super( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; if ( distance >= 0 ) { val = ADD_LONG( distance, exc->threshold - exc->phase + compensation ) & -exc->period; val = ADD_LONG( val, exc->phase ); if ( val < 0 ) val = exc->phase; } else { val = NEG_LONG( SUB_LONG( exc->threshold - exc->phase + compensation, distance ) & -exc->period ); val = SUB_LONG( val, exc->phase ); if ( val > 0 ) val = -exc->phase; } return val; } /************************************************************************** * * @Function: * Round_Super_45 * * @Description: * Super-rounds value to grid after adding engine compensation. * * @Input: * distance :: * The distance to round. * * compensation :: * The engine compensation. * * @Return: * Rounded distance. * * @Note: * There is a separate function for Round_Super_45() as we may need * greater precision. */ static FT_F26Dot6 Round_Super_45( TT_ExecContext exc, FT_F26Dot6 distance, FT_F26Dot6 compensation ) { FT_F26Dot6 val; if ( distance >= 0 ) { val = ( ADD_LONG( distance, exc->threshold - exc->phase + compensation ) / exc->period ) * exc->period; val = ADD_LONG( val, exc->phase ); if ( val < 0 ) val = exc->phase; } else { val = NEG_LONG( ( SUB_LONG( exc->threshold - exc->phase + compensation, distance ) / exc->period ) * exc->period ); val = SUB_LONG( val, exc->phase ); if ( val > 0 ) val = -exc->phase; } return val; } /************************************************************************** * * @Function: * Compute_Round * * @Description: * Sets the rounding mode. * * @Input: * round_mode :: * The rounding mode to be used. */ static void Compute_Round( TT_ExecContext exc, FT_Byte round_mode ) { switch ( round_mode ) { case TT_Round_Off: exc->func_round = (TT_Round_Func)Round_None; break; case TT_Round_To_Grid: exc->func_round = (TT_Round_Func)Round_To_Grid; break; case TT_Round_Up_To_Grid: exc->func_round = (TT_Round_Func)Round_Up_To_Grid; break; case TT_Round_Down_To_Grid: exc->func_round = (TT_Round_Func)Round_Down_To_Grid; break; case TT_Round_To_Half_Grid: exc->func_round = (TT_Round_Func)Round_To_Half_Grid; break; case TT_Round_To_Double_Grid: exc->func_round = (TT_Round_Func)Round_To_Double_Grid; break; case TT_Round_Super: exc->func_round = (TT_Round_Func)Round_Super; break; case TT_Round_Super_45: exc->func_round = (TT_Round_Func)Round_Super_45; break; } } /************************************************************************** * * @Function: * SetSuperRound * * @Description: * Sets Super Round parameters. * * @Input: * GridPeriod :: * The grid period. * * selector :: * The SROUND opcode. */ static void SetSuperRound( TT_ExecContext exc, FT_F2Dot14 GridPeriod, FT_Long selector ) { switch ( (FT_Int)( selector & 0xC0 ) ) { case 0: exc->period = GridPeriod / 2; break; case 0x40: exc->period = GridPeriod; break; case 0x80: exc->period = GridPeriod * 2; break; /* This opcode is reserved, but... */ case 0xC0: exc->period = GridPeriod; break; } switch ( (FT_Int)( selector & 0x30 ) ) { case 0: exc->phase = 0; break; case 0x10: exc->phase = exc->period / 4; break; case 0x20: exc->phase = exc->period / 2; break; case 0x30: exc->phase = exc->period * 3 / 4; break; } if ( ( selector & 0x0F ) == 0 ) exc->threshold = exc->period - 1; else exc->threshold = ( (FT_Int)( selector & 0x0F ) - 4 ) * exc->period / 8; /* convert to F26Dot6 format */ exc->period >>= 8; exc->phase >>= 8; exc->threshold >>= 8; } /************************************************************************** * * @Function: * Project * * @Description: * Computes the projection of vector given by (v2-v1) along the * current projection vector. * * @Input: * v1 :: * First input vector. * v2 :: * Second input vector. * * @Return: * The distance in F26dot6 format. */ static FT_F26Dot6 Project( TT_ExecContext exc, FT_Pos dx, FT_Pos dy ) { return TT_DotFix14( dx, dy, exc->GS.projVector.x, exc->GS.projVector.y ); } /************************************************************************** * * @Function: * Dual_Project * * @Description: * Computes the projection of the vector given by (v2-v1) along the * current dual vector. * * @Input: * v1 :: * First input vector. * v2 :: * Second input vector. * * @Return: * The distance in F26dot6 format. */ static FT_F26Dot6 Dual_Project( TT_ExecContext exc, FT_Pos dx, FT_Pos dy ) { return TT_DotFix14( dx, dy, exc->GS.dualVector.x, exc->GS.dualVector.y ); } /************************************************************************** * * @Function: * Project_x * * @Description: * Computes the projection of the vector given by (v2-v1) along the * horizontal axis. * * @Input: * v1 :: * First input vector. * v2 :: * Second input vector. * * @Return: * The distance in F26dot6 format. */ static FT_F26Dot6 Project_x( TT_ExecContext exc, FT_Pos dx, FT_Pos dy ) { FT_UNUSED( exc ); FT_UNUSED( dy ); return dx; } /************************************************************************** * * @Function: * Project_y * * @Description: * Computes the projection of the vector given by (v2-v1) along the * vertical axis. * * @Input: * v1 :: * First input vector. * v2 :: * Second input vector. * * @Return: * The distance in F26dot6 format. */ static FT_F26Dot6 Project_y( TT_ExecContext exc, FT_Pos dx, FT_Pos dy ) { FT_UNUSED( exc ); FT_UNUSED( dx ); return dy; } /************************************************************************** * * @Function: * Compute_Funcs * * @Description: * Computes the projection and movement function pointers according * to the current graphics state. */ static void Compute_Funcs( TT_ExecContext exc ) { if ( exc->GS.freeVector.x == 0x4000 ) exc->F_dot_P = exc->GS.projVector.x; else if ( exc->GS.freeVector.y == 0x4000 ) exc->F_dot_P = exc->GS.projVector.y; else exc->F_dot_P = ( (FT_Long)exc->GS.projVector.x * exc->GS.freeVector.x + (FT_Long)exc->GS.projVector.y * exc->GS.freeVector.y ) >> 14; if ( exc->GS.projVector.x == 0x4000 ) exc->func_project = (TT_Project_Func)Project_x; else if ( exc->GS.projVector.y == 0x4000 ) exc->func_project = (TT_Project_Func)Project_y; else exc->func_project = (TT_Project_Func)Project; if ( exc->GS.dualVector.x == 0x4000 ) exc->func_dualproj = (TT_Project_Func)Project_x; else if ( exc->GS.dualVector.y == 0x4000 ) exc->func_dualproj = (TT_Project_Func)Project_y; else exc->func_dualproj = (TT_Project_Func)Dual_Project; exc->func_move = (TT_Move_Func)Direct_Move; exc->func_move_orig = (TT_Move_Func)Direct_Move_Orig; if ( exc->F_dot_P == 0x4000L ) { if ( exc->GS.freeVector.x == 0x4000 ) { exc->func_move = (TT_Move_Func)Direct_Move_X; exc->func_move_orig = (TT_Move_Func)Direct_Move_Orig_X; } else if ( exc->GS.freeVector.y == 0x4000 ) { exc->func_move = (TT_Move_Func)Direct_Move_Y; exc->func_move_orig = (TT_Move_Func)Direct_Move_Orig_Y; } } /* at small sizes, F_dot_P can become too small, resulting */ /* in overflows and `spikes' in a number of glyphs like `w'. */ if ( FT_ABS( exc->F_dot_P ) < 0x400L ) exc->F_dot_P = 0x4000L; /* Disable cached aspect ratio */ exc->tt_metrics.ratio = 0; } /************************************************************************** * * @Function: * Normalize * * @Description: * Norms a vector. * * @Input: * Vx :: * The horizontal input vector coordinate. * Vy :: * The vertical input vector coordinate. * * @Output: * R :: * The normed unit vector. * * @Return: * Returns FAILURE if a vector parameter is zero. * * @Note: * In case Vx and Vy are both zero, `Normalize' returns SUCCESS, and * R is undefined. */ static FT_Bool Normalize( FT_F26Dot6 Vx, FT_F26Dot6 Vy, FT_UnitVector* R ) { FT_Vector V; if ( Vx == 0 && Vy == 0 ) { /* XXX: UNDOCUMENTED! It seems that it is possible to try */ /* to normalize the vector (0,0). Return immediately. */ return SUCCESS; } V.x = Vx; V.y = Vy; FT_Vector_NormLen( &V ); R->x = (FT_F2Dot14)( V.x / 4 ); R->y = (FT_F2Dot14)( V.y / 4 ); return SUCCESS; } /************************************************************************** * * Here we start with the implementation of the various opcodes. * */ #define ARRAY_BOUND_ERROR \ do \ { \ exc->error = FT_THROW( Invalid_Reference ); \ return; \ } while (0) /************************************************************************** * * MPPEM[]: Measure Pixel Per EM * Opcode range: 0x4B * Stack: --> Euint16 */ static void Ins_MPPEM( TT_ExecContext exc, FT_Long* args ) { args[0] = exc->func_cur_ppem( exc ); } /************************************************************************** * * MPS[]: Measure Point Size * Opcode range: 0x4C * Stack: --> Euint16 */ static void Ins_MPS( TT_ExecContext exc, FT_Long* args ) { if ( NO_SUBPIXEL_HINTING ) { /* Microsoft's GDI bytecode interpreter always returns value 12; */ /* we return the current PPEM value instead. */ args[0] = exc->func_cur_ppem( exc ); } else { /* A possible practical application of the MPS instruction is to */ /* implement optical scaling and similar features, which should be */ /* based on perceptual attributes, thus independent of the */ /* resolution. */ args[0] = exc->pointSize; } } /************************************************************************** * * DUP[]: DUPlicate the stack's top element * Opcode range: 0x20 * Stack: StkElt --> StkElt StkElt */ static void Ins_DUP( FT_Long* args ) { args[1] = args[0]; } /************************************************************************** * * POP[]: POP the stack's top element * Opcode range: 0x21 * Stack: StkElt --> */ static void Ins_POP( void ) { /* nothing to do */ } /************************************************************************** * * CLEAR[]: CLEAR the entire stack * Opcode range: 0x22 * Stack: StkElt... --> */ static void Ins_CLEAR( TT_ExecContext exc ) { exc->new_top = 0; } /************************************************************************** * * SWAP[]: SWAP the stack's top two elements * Opcode range: 0x23 * Stack: 2 * StkElt --> 2 * StkElt */ static void Ins_SWAP( FT_Long* args ) { FT_Long L; L = args[0]; args[0] = args[1]; args[1] = L; } /************************************************************************** * * DEPTH[]: return the stack DEPTH * Opcode range: 0x24 * Stack: --> uint32 */ static void Ins_DEPTH( TT_ExecContext exc, FT_Long* args ) { args[0] = exc->top; } /************************************************************************** * * LT[]: Less Than * Opcode range: 0x50 * Stack: int32? int32? --> bool */ static void Ins_LT( FT_Long* args ) { args[0] = ( args[0] < args[1] ); } /************************************************************************** * * LTEQ[]: Less Than or EQual * Opcode range: 0x51 * Stack: int32? int32? --> bool */ static void Ins_LTEQ( FT_Long* args ) { args[0] = ( args[0] <= args[1] ); } /************************************************************************** * * GT[]: Greater Than * Opcode range: 0x52 * Stack: int32? int32? --> bool */ static void Ins_GT( FT_Long* args ) { args[0] = ( args[0] > args[1] ); } /************************************************************************** * * GTEQ[]: Greater Than or EQual * Opcode range: 0x53 * Stack: int32? int32? --> bool */ static void Ins_GTEQ( FT_Long* args ) { args[0] = ( args[0] >= args[1] ); } /************************************************************************** * * EQ[]: EQual * Opcode range: 0x54 * Stack: StkElt StkElt --> bool */ static void Ins_EQ( FT_Long* args ) { args[0] = ( args[0] == args[1] ); } /************************************************************************** * * NEQ[]: Not EQual * Opcode range: 0x55 * Stack: StkElt StkElt --> bool */ static void Ins_NEQ( FT_Long* args ) { args[0] = ( args[0] != args[1] ); } /************************************************************************** * * ODD[]: Is ODD * Opcode range: 0x56 * Stack: f26.6 --> bool */ static void Ins_ODD( TT_ExecContext exc, FT_Long* args ) { args[0] = ( ( exc->func_round( exc, args[0], 0 ) & 127 ) == 64 ); } /************************************************************************** * * EVEN[]: Is EVEN * Opcode range: 0x57 * Stack: f26.6 --> bool */ static void Ins_EVEN( TT_ExecContext exc, FT_Long* args ) { args[0] = ( ( exc->func_round( exc, args[0], 0 ) & 127 ) == 0 ); } /************************************************************************** * * AND[]: logical AND * Opcode range: 0x5A * Stack: uint32 uint32 --> uint32 */ static void Ins_AND( FT_Long* args ) { args[0] = ( args[0] && args[1] ); } /************************************************************************** * * OR[]: logical OR * Opcode range: 0x5B * Stack: uint32 uint32 --> uint32 */ static void Ins_OR( FT_Long* args ) { args[0] = ( args[0] || args[1] ); } /************************************************************************** * * NOT[]: logical NOT * Opcode range: 0x5C * Stack: StkElt --> uint32 */ static void Ins_NOT( FT_Long* args ) { args[0] = !args[0]; } /************************************************************************** * * ADD[]: ADD * Opcode range: 0x60 * Stack: f26.6 f26.6 --> f26.6 */ static void Ins_ADD( FT_Long* args ) { args[0] = ADD_LONG( args[0], args[1] ); } /************************************************************************** * * SUB[]: SUBtract * Opcode range: 0x61 * Stack: f26.6 f26.6 --> f26.6 */ static void Ins_SUB( FT_Long* args ) { args[0] = SUB_LONG( args[0], args[1] ); } /************************************************************************** * * DIV[]: DIVide * Opcode range: 0x62 * Stack: f26.6 f26.6 --> f26.6 */ static void Ins_DIV( TT_ExecContext exc, FT_Long* args ) { if ( args[1] == 0 ) exc->error = FT_THROW( Divide_By_Zero ); else args[0] = FT_MulDiv_No_Round( args[0], 64L, args[1] ); } /************************************************************************** * * MUL[]: MULtiply * Opcode range: 0x63 * Stack: f26.6 f26.6 --> f26.6 */ static void Ins_MUL( FT_Long* args ) { args[0] = FT_MulDiv( args[0], args[1], 64L ); } /************************************************************************** * * ABS[]: ABSolute value * Opcode range: 0x64 * Stack: f26.6 --> f26.6 */ static void Ins_ABS( FT_Long* args ) { if ( args[0] < 0 ) args[0] = NEG_LONG( args[0] ); } /************************************************************************** * * NEG[]: NEGate * Opcode range: 0x65 * Stack: f26.6 --> f26.6 */ static void Ins_NEG( FT_Long* args ) { args[0] = NEG_LONG( args[0] ); } /************************************************************************** * * FLOOR[]: FLOOR * Opcode range: 0x66 * Stack: f26.6 --> f26.6 */ static void Ins_FLOOR( FT_Long* args ) { args[0] = FT_PIX_FLOOR( args[0] ); } /************************************************************************** * * CEILING[]: CEILING * Opcode range: 0x67 * Stack: f26.6 --> f26.6 */ static void Ins_CEILING( FT_Long* args ) { args[0] = FT_PIX_CEIL_LONG( args[0] ); } /************************************************************************** * * RS[]: Read Store * Opcode range: 0x43 * Stack: uint32 --> uint32 */ static void Ins_RS( TT_ExecContext exc, FT_Long* args ) { FT_ULong I = (FT_ULong)args[0]; if ( BOUNDSL( I, exc->storeSize ) ) { if ( exc->pedantic_hinting ) ARRAY_BOUND_ERROR; else args[0] = 0; } else { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* subpixel hinting - avoid Typeman Dstroke and */ /* IStroke and Vacuform rounds */ if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && ( ( I == 24 && ( exc->face->sph_found_func_flags & ( SPH_FDEF_SPACING_1 | SPH_FDEF_SPACING_2 ) ) ) || ( I == 22 && ( exc->sph_in_func_flags & SPH_FDEF_TYPEMAN_STROKES ) ) || ( I == 8 && ( exc->face->sph_found_func_flags & SPH_FDEF_VACUFORM_ROUND_1 ) && exc->iup_called ) ) ) args[0] = 0; else #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ args[0] = exc->storage[I]; } } /************************************************************************** * * WS[]: Write Store * Opcode range: 0x42 * Stack: uint32 uint32 --> */ static void Ins_WS( TT_ExecContext exc, FT_Long* args ) { FT_ULong I = (FT_ULong)args[0]; if ( BOUNDSL( I, exc->storeSize ) ) { if ( exc->pedantic_hinting ) ARRAY_BOUND_ERROR; } else exc->storage[I] = args[1]; } /************************************************************************** * * WCVTP[]: Write CVT in Pixel units * Opcode range: 0x44 * Stack: f26.6 uint32 --> */ static void Ins_WCVTP( TT_ExecContext exc, FT_Long* args ) { FT_ULong I = (FT_ULong)args[0]; if ( BOUNDSL( I, exc->cvtSize ) ) { if ( exc->pedantic_hinting ) ARRAY_BOUND_ERROR; } else exc->func_write_cvt( exc, I, args[1] ); } /************************************************************************** * * WCVTF[]: Write CVT in Funits * Opcode range: 0x70 * Stack: uint32 uint32 --> */ static void Ins_WCVTF( TT_ExecContext exc, FT_Long* args ) { FT_ULong I = (FT_ULong)args[0]; if ( BOUNDSL( I, exc->cvtSize ) ) { if ( exc->pedantic_hinting ) ARRAY_BOUND_ERROR; } else exc->cvt[I] = FT_MulFix( args[1], exc->tt_metrics.scale ); } /************************************************************************** * * RCVT[]: Read CVT * Opcode range: 0x45 * Stack: uint32 --> f26.6 */ static void Ins_RCVT( TT_ExecContext exc, FT_Long* args ) { FT_ULong I = (FT_ULong)args[0]; if ( BOUNDSL( I, exc->cvtSize ) ) { if ( exc->pedantic_hinting ) ARRAY_BOUND_ERROR; else args[0] = 0; } else args[0] = exc->func_read_cvt( exc, I ); } /************************************************************************** * * AA[]: Adjust Angle * Opcode range: 0x7F * Stack: uint32 --> */ static void Ins_AA( void ) { /* intentionally no longer supported */ } /************************************************************************** * * DEBUG[]: DEBUG. Unsupported. * Opcode range: 0x4F * Stack: uint32 --> * * Note: The original instruction pops a value from the stack. */ static void Ins_DEBUG( TT_ExecContext exc ) { exc->error = FT_THROW( Debug_OpCode ); } /************************************************************************** * * ROUND[ab]: ROUND value * Opcode range: 0x68-0x6B * Stack: f26.6 --> f26.6 */ static void Ins_ROUND( TT_ExecContext exc, FT_Long* args ) { args[0] = exc->func_round( exc, args[0], exc->tt_metrics.compensations[exc->opcode - 0x68] ); } /************************************************************************** * * NROUND[ab]: No ROUNDing of value * Opcode range: 0x6C-0x6F * Stack: f26.6 --> f26.6 */ static void Ins_NROUND( TT_ExecContext exc, FT_Long* args ) { args[0] = Round_None( exc, args[0], exc->tt_metrics.compensations[exc->opcode - 0x6C] ); } /************************************************************************** * * MAX[]: MAXimum * Opcode range: 0x8B * Stack: int32? int32? --> int32 */ static void Ins_MAX( FT_Long* args ) { if ( args[1] > args[0] ) args[0] = args[1]; } /************************************************************************** * * MIN[]: MINimum * Opcode range: 0x8C * Stack: int32? int32? --> int32 */ static void Ins_MIN( FT_Long* args ) { if ( args[1] < args[0] ) args[0] = args[1]; } /************************************************************************** * * MINDEX[]: Move INDEXed element * Opcode range: 0x26 * Stack: int32? --> StkElt */ static void Ins_MINDEX( TT_ExecContext exc, FT_Long* args ) { FT_Long L, K; L = args[0]; if ( L <= 0 || L > exc->args ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); } else { K = exc->stack[exc->args - L]; FT_ARRAY_MOVE( &exc->stack[exc->args - L ], &exc->stack[exc->args - L + 1], ( L - 1 ) ); exc->stack[exc->args - 1] = K; } } /************************************************************************** * * CINDEX[]: Copy INDEXed element * Opcode range: 0x25 * Stack: int32 --> StkElt */ static void Ins_CINDEX( TT_ExecContext exc, FT_Long* args ) { FT_Long L; L = args[0]; if ( L <= 0 || L > exc->args ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); args[0] = 0; } else args[0] = exc->stack[exc->args - L]; } /************************************************************************** * * ROLL[]: ROLL top three elements * Opcode range: 0x8A * Stack: 3 * StkElt --> 3 * StkElt */ static void Ins_ROLL( FT_Long* args ) { FT_Long A, B, C; A = args[2]; B = args[1]; C = args[0]; args[2] = C; args[1] = A; args[0] = B; } /************************************************************************** * * MANAGING THE FLOW OF CONTROL * */ /************************************************************************** * * SLOOP[]: Set LOOP variable * Opcode range: 0x17 * Stack: int32? --> */ static void Ins_SLOOP( TT_ExecContext exc, FT_Long* args ) { if ( args[0] < 0 ) exc->error = FT_THROW( Bad_Argument ); else { /* we heuristically limit the number of loops to 16 bits */ exc->GS.loop = args[0] > 0xFFFFL ? 0xFFFFL : args[0]; } } static FT_Bool SkipCode( TT_ExecContext exc ) { exc->IP += exc->length; if ( exc->IP < exc->codeSize ) { exc->opcode = exc->code[exc->IP]; exc->length = opcode_length[exc->opcode]; if ( exc->length < 0 ) { if ( exc->IP + 1 >= exc->codeSize ) goto Fail_Overflow; exc->length = 2 - exc->length * exc->code[exc->IP + 1]; } if ( exc->IP + exc->length <= exc->codeSize ) return SUCCESS; } Fail_Overflow: exc->error = FT_THROW( Code_Overflow ); return FAILURE; } /************************************************************************** * * IF[]: IF test * Opcode range: 0x58 * Stack: StkElt --> */ static void Ins_IF( TT_ExecContext exc, FT_Long* args ) { FT_Int nIfs; FT_Bool Out; if ( args[0] != 0 ) return; nIfs = 1; Out = 0; do { if ( SkipCode( exc ) == FAILURE ) return; switch ( exc->opcode ) { case 0x58: /* IF */ nIfs++; break; case 0x1B: /* ELSE */ Out = FT_BOOL( nIfs == 1 ); break; case 0x59: /* EIF */ nIfs--; Out = FT_BOOL( nIfs == 0 ); break; } } while ( Out == 0 ); } /************************************************************************** * * ELSE[]: ELSE * Opcode range: 0x1B * Stack: --> */ static void Ins_ELSE( TT_ExecContext exc ) { FT_Int nIfs; nIfs = 1; do { if ( SkipCode( exc ) == FAILURE ) return; switch ( exc->opcode ) { case 0x58: /* IF */ nIfs++; break; case 0x59: /* EIF */ nIfs--; break; } } while ( nIfs != 0 ); } /************************************************************************** * * EIF[]: End IF * Opcode range: 0x59 * Stack: --> */ static void Ins_EIF( void ) { /* nothing to do */ } /************************************************************************** * * JMPR[]: JuMP Relative * Opcode range: 0x1C * Stack: int32 --> */ static void Ins_JMPR( TT_ExecContext exc, FT_Long* args ) { if ( args[0] == 0 && exc->args == 0 ) { exc->error = FT_THROW( Bad_Argument ); return; } exc->IP += args[0]; if ( exc->IP < 0 || ( exc->callTop > 0 && exc->IP > exc->callStack[exc->callTop - 1].Def->end ) ) { exc->error = FT_THROW( Bad_Argument ); return; } exc->step_ins = FALSE; if ( args[0] < 0 ) { if ( ++exc->neg_jump_counter > exc->neg_jump_counter_max ) exc->error = FT_THROW( Execution_Too_Long ); } } /************************************************************************** * * JROT[]: Jump Relative On True * Opcode range: 0x78 * Stack: StkElt int32 --> */ static void Ins_JROT( TT_ExecContext exc, FT_Long* args ) { if ( args[1] != 0 ) Ins_JMPR( exc, args ); } /************************************************************************** * * JROF[]: Jump Relative On False * Opcode range: 0x79 * Stack: StkElt int32 --> */ static void Ins_JROF( TT_ExecContext exc, FT_Long* args ) { if ( args[1] == 0 ) Ins_JMPR( exc, args ); } /************************************************************************** * * DEFINING AND USING FUNCTIONS AND INSTRUCTIONS * */ /************************************************************************** * * FDEF[]: Function DEFinition * Opcode range: 0x2C * Stack: uint32 --> */ static void Ins_FDEF( TT_ExecContext exc, FT_Long* args ) { FT_ULong n; TT_DefRecord* rec; TT_DefRecord* limit; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* arguments to opcodes are skipped by `SKIP_Code' */ FT_Byte opcode_pattern[9][12] = { /* #0 inline delta function 1 */ { 0x4B, /* PPEM */ 0x53, /* GTEQ */ 0x23, /* SWAP */ 0x4B, /* PPEM */ 0x51, /* LTEQ */ 0x5A, /* AND */ 0x58, /* IF */ 0x38, /* SHPIX */ 0x1B, /* ELSE */ 0x21, /* POP */ 0x21, /* POP */ 0x59 /* EIF */ }, /* #1 inline delta function 2 */ { 0x4B, /* PPEM */ 0x54, /* EQ */ 0x58, /* IF */ 0x38, /* SHPIX */ 0x1B, /* ELSE */ 0x21, /* POP */ 0x21, /* POP */ 0x59 /* EIF */ }, /* #2 diagonal stroke function */ { 0x20, /* DUP */ 0x20, /* DUP */ 0xB0, /* PUSHB_1 */ /* 1 */ 0x60, /* ADD */ 0x46, /* GC_cur */ 0xB0, /* PUSHB_1 */ /* 64 */ 0x23, /* SWAP */ 0x42 /* WS */ }, /* #3 VacuFormRound function */ { 0x45, /* RCVT */ 0x23, /* SWAP */ 0x46, /* GC_cur */ 0x60, /* ADD */ 0x20, /* DUP */ 0xB0 /* PUSHB_1 */ /* 38 */ }, /* #4 TTFautohint bytecode (old) */ { 0x20, /* DUP */ 0x64, /* ABS */ 0xB0, /* PUSHB_1 */ /* 32 */ 0x60, /* ADD */ 0x66, /* FLOOR */ 0x23, /* SWAP */ 0xB0 /* PUSHB_1 */ }, /* #5 spacing function 1 */ { 0x01, /* SVTCA_x */ 0xB0, /* PUSHB_1 */ /* 24 */ 0x43, /* RS */ 0x58 /* IF */ }, /* #6 spacing function 2 */ { 0x01, /* SVTCA_x */ 0x18, /* RTG */ 0xB0, /* PUSHB_1 */ /* 24 */ 0x43, /* RS */ 0x58 /* IF */ }, /* #7 TypeMan Talk DiagEndCtrl function */ { 0x01, /* SVTCA_x */ 0x20, /* DUP */ 0xB0, /* PUSHB_1 */ /* 3 */ 0x25, /* CINDEX */ }, /* #8 TypeMan Talk Align */ { 0x06, /* SPVTL */ 0x7D, /* RDTG */ }, }; FT_UShort opcode_patterns = 9; FT_UShort opcode_pointer[9] = { 0, 0, 0, 0, 0, 0, 0, 0, 0 }; FT_UShort opcode_size[9] = { 12, 8, 8, 6, 7, 4, 5, 4, 2 }; FT_UShort i; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ /* FDEF is only allowed in `prep' or `fpgm' */ if ( exc->curRange == tt_coderange_glyph ) { exc->error = FT_THROW( DEF_In_Glyf_Bytecode ); return; } /* some font programs are broken enough to redefine functions! */ /* We will then parse the current table. */ rec = exc->FDefs; limit = rec + exc->numFDefs; n = (FT_ULong)args[0]; for ( ; rec < limit; rec++ ) { if ( rec->opc == n ) break; } if ( rec == limit ) { /* check that there is enough room for new functions */ if ( exc->numFDefs >= exc->maxFDefs ) { exc->error = FT_THROW( Too_Many_Function_Defs ); return; } exc->numFDefs++; } /* Although FDEF takes unsigned 32-bit integer, */ /* func # must be within unsigned 16-bit integer */ if ( n > 0xFFFFU ) { exc->error = FT_THROW( Too_Many_Function_Defs ); return; } rec->range = exc->curRange; rec->opc = (FT_UInt16)n; rec->start = exc->IP + 1; rec->active = TRUE; rec->inline_delta = FALSE; rec->sph_fdef_flags = 0x0000; if ( n > exc->maxFunc ) exc->maxFunc = (FT_UInt16)n; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* We don't know for sure these are typeman functions, */ /* however they are only active when RS 22 is called */ if ( n >= 64 && n <= 66 ) rec->sph_fdef_flags |= SPH_FDEF_TYPEMAN_STROKES; #endif /* Now skip the whole function definition. */ /* We don't allow nested IDEFS & FDEFs. */ while ( SkipCode( exc ) == SUCCESS ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY ) { for ( i = 0; i < opcode_patterns; i++ ) { if ( opcode_pointer[i] < opcode_size[i] && exc->opcode == opcode_pattern[i][opcode_pointer[i]] ) { opcode_pointer[i] += 1; if ( opcode_pointer[i] == opcode_size[i] ) { FT_TRACE6(( "sph: Function %d, opcode ptrn: %d, %s %s\n", i, n, exc->face->root.family_name, exc->face->root.style_name )); switch ( i ) { case 0: rec->sph_fdef_flags |= SPH_FDEF_INLINE_DELTA_1; exc->face->sph_found_func_flags |= SPH_FDEF_INLINE_DELTA_1; break; case 1: rec->sph_fdef_flags |= SPH_FDEF_INLINE_DELTA_2; exc->face->sph_found_func_flags |= SPH_FDEF_INLINE_DELTA_2; break; case 2: switch ( n ) { /* needs to be implemented still */ case 58: rec->sph_fdef_flags |= SPH_FDEF_DIAGONAL_STROKE; exc->face->sph_found_func_flags |= SPH_FDEF_DIAGONAL_STROKE; } break; case 3: switch ( n ) { case 0: rec->sph_fdef_flags |= SPH_FDEF_VACUFORM_ROUND_1; exc->face->sph_found_func_flags |= SPH_FDEF_VACUFORM_ROUND_1; } break; case 4: /* probably not necessary to detect anymore */ rec->sph_fdef_flags |= SPH_FDEF_TTFAUTOHINT_1; exc->face->sph_found_func_flags |= SPH_FDEF_TTFAUTOHINT_1; break; case 5: switch ( n ) { case 0: case 1: case 2: case 4: case 7: case 8: rec->sph_fdef_flags |= SPH_FDEF_SPACING_1; exc->face->sph_found_func_flags |= SPH_FDEF_SPACING_1; } break; case 6: switch ( n ) { case 0: case 1: case 2: case 4: case 7: case 8: rec->sph_fdef_flags |= SPH_FDEF_SPACING_2; exc->face->sph_found_func_flags |= SPH_FDEF_SPACING_2; } break; case 7: rec->sph_fdef_flags |= SPH_FDEF_TYPEMAN_DIAGENDCTRL; exc->face->sph_found_func_flags |= SPH_FDEF_TYPEMAN_DIAGENDCTRL; break; case 8: #if 0 rec->sph_fdef_flags |= SPH_FDEF_TYPEMAN_DIAGENDCTRL; exc->face->sph_found_func_flags |= SPH_FDEF_TYPEMAN_DIAGENDCTRL; #endif break; } opcode_pointer[i] = 0; } } else opcode_pointer[i] = 0; } /* Set sph_compatibility_mode only when deltas are detected */ exc->face->sph_compatibility_mode = ( ( exc->face->sph_found_func_flags & SPH_FDEF_INLINE_DELTA_1 ) | ( exc->face->sph_found_func_flags & SPH_FDEF_INLINE_DELTA_2 ) ); } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ switch ( exc->opcode ) { case 0x89: /* IDEF */ case 0x2C: /* FDEF */ exc->error = FT_THROW( Nested_DEFS ); return; case 0x2D: /* ENDF */ rec->end = exc->IP; return; } } } /************************************************************************** * * ENDF[]: END Function definition * Opcode range: 0x2D * Stack: --> */ static void Ins_ENDF( TT_ExecContext exc ) { TT_CallRec* pRec; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY exc->sph_in_func_flags = 0x0000; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ if ( exc->callTop <= 0 ) /* We encountered an ENDF without a call */ { exc->error = FT_THROW( ENDF_In_Exec_Stream ); return; } exc->callTop--; pRec = &exc->callStack[exc->callTop]; pRec->Cur_Count--; exc->step_ins = FALSE; if ( pRec->Cur_Count > 0 ) { exc->callTop++; exc->IP = pRec->Def->start; } else /* Loop through the current function */ Ins_Goto_CodeRange( exc, pRec->Caller_Range, pRec->Caller_IP ); /* Exit the current call frame. */ /* NOTE: If the last instruction of a program is a */ /* CALL or LOOPCALL, the return address is */ /* always out of the code range. This is a */ /* valid address, and it is why we do not test */ /* the result of Ins_Goto_CodeRange() here! */ } /************************************************************************** * * CALL[]: CALL function * Opcode range: 0x2B * Stack: uint32? --> */ static void Ins_CALL( TT_ExecContext exc, FT_Long* args ) { FT_ULong F; TT_CallRec* pCrec; TT_DefRecord* def; /* first of all, check the index */ F = (FT_ULong)args[0]; if ( BOUNDSL( F, exc->maxFunc + 1 ) ) goto Fail; /* Except for some old Apple fonts, all functions in a TrueType */ /* font are defined in increasing order, starting from 0. This */ /* means that we normally have */ /* */ /* exc->maxFunc+1 == exc->numFDefs */ /* exc->FDefs[n].opc == n for n in 0..exc->maxFunc */ /* */ /* If this isn't true, we need to look up the function table. */ def = exc->FDefs + F; if ( exc->maxFunc + 1 != exc->numFDefs || def->opc != F ) { /* look up the FDefs table */ TT_DefRecord* limit; def = exc->FDefs; limit = def + exc->numFDefs; while ( def < limit && def->opc != F ) def++; if ( def == limit ) goto Fail; } /* check that the function is active */ if ( !def->active ) goto Fail; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && ( ( exc->iup_called && ( exc->sph_tweak_flags & SPH_TWEAK_NO_CALL_AFTER_IUP ) ) || ( def->sph_fdef_flags & SPH_FDEF_VACUFORM_ROUND_1 ) ) ) goto Fail; else exc->sph_in_func_flags = def->sph_fdef_flags; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ /* check the call stack */ if ( exc->callTop >= exc->callSize ) { exc->error = FT_THROW( Stack_Overflow ); return; } pCrec = exc->callStack + exc->callTop; pCrec->Caller_Range = exc->curRange; pCrec->Caller_IP = exc->IP + 1; pCrec->Cur_Count = 1; pCrec->Def = def; exc->callTop++; Ins_Goto_CodeRange( exc, def->range, def->start ); exc->step_ins = FALSE; return; Fail: exc->error = FT_THROW( Invalid_Reference ); } /************************************************************************** * * LOOPCALL[]: LOOP and CALL function * Opcode range: 0x2A * Stack: uint32? Eint16? --> */ static void Ins_LOOPCALL( TT_ExecContext exc, FT_Long* args ) { FT_ULong F; TT_CallRec* pCrec; TT_DefRecord* def; /* first of all, check the index */ F = (FT_ULong)args[1]; if ( BOUNDSL( F, exc->maxFunc + 1 ) ) goto Fail; /* Except for some old Apple fonts, all functions in a TrueType */ /* font are defined in increasing order, starting from 0. This */ /* means that we normally have */ /* */ /* exc->maxFunc+1 == exc->numFDefs */ /* exc->FDefs[n].opc == n for n in 0..exc->maxFunc */ /* */ /* If this isn't true, we need to look up the function table. */ def = exc->FDefs + F; if ( exc->maxFunc + 1 != exc->numFDefs || def->opc != F ) { /* look up the FDefs table */ TT_DefRecord* limit; def = exc->FDefs; limit = def + exc->numFDefs; while ( def < limit && def->opc != F ) def++; if ( def == limit ) goto Fail; } /* check that the function is active */ if ( !def->active ) goto Fail; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && ( def->sph_fdef_flags & SPH_FDEF_VACUFORM_ROUND_1 ) ) goto Fail; else exc->sph_in_func_flags = def->sph_fdef_flags; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ /* check stack */ if ( exc->callTop >= exc->callSize ) { exc->error = FT_THROW( Stack_Overflow ); return; } if ( args[0] > 0 ) { pCrec = exc->callStack + exc->callTop; pCrec->Caller_Range = exc->curRange; pCrec->Caller_IP = exc->IP + 1; pCrec->Cur_Count = (FT_Int)args[0]; pCrec->Def = def; exc->callTop++; Ins_Goto_CodeRange( exc, def->range, def->start ); exc->step_ins = FALSE; exc->loopcall_counter += (FT_ULong)args[0]; if ( exc->loopcall_counter > exc->loopcall_counter_max ) exc->error = FT_THROW( Execution_Too_Long ); } return; Fail: exc->error = FT_THROW( Invalid_Reference ); } /************************************************************************** * * IDEF[]: Instruction DEFinition * Opcode range: 0x89 * Stack: Eint8 --> */ static void Ins_IDEF( TT_ExecContext exc, FT_Long* args ) { TT_DefRecord* def; TT_DefRecord* limit; /* we enable IDEF only in `prep' or `fpgm' */ if ( exc->curRange == tt_coderange_glyph ) { exc->error = FT_THROW( DEF_In_Glyf_Bytecode ); return; } /* First of all, look for the same function in our table */ def = exc->IDefs; limit = def + exc->numIDefs; for ( ; def < limit; def++ ) if ( def->opc == (FT_ULong)args[0] ) break; if ( def == limit ) { /* check that there is enough room for a new instruction */ if ( exc->numIDefs >= exc->maxIDefs ) { exc->error = FT_THROW( Too_Many_Instruction_Defs ); return; } exc->numIDefs++; } /* opcode must be unsigned 8-bit integer */ if ( 0 > args[0] || args[0] > 0x00FF ) { exc->error = FT_THROW( Too_Many_Instruction_Defs ); return; } def->opc = (FT_Byte)args[0]; def->start = exc->IP + 1; def->range = exc->curRange; def->active = TRUE; if ( (FT_ULong)args[0] > exc->maxIns ) exc->maxIns = (FT_Byte)args[0]; /* Now skip the whole function definition. */ /* We don't allow nested IDEFs & FDEFs. */ while ( SkipCode( exc ) == SUCCESS ) { switch ( exc->opcode ) { case 0x89: /* IDEF */ case 0x2C: /* FDEF */ exc->error = FT_THROW( Nested_DEFS ); return; case 0x2D: /* ENDF */ def->end = exc->IP; return; } } } /************************************************************************** * * PUSHING DATA ONTO THE INTERPRETER STACK * */ /************************************************************************** * * NPUSHB[]: PUSH N Bytes * Opcode range: 0x40 * Stack: --> uint32... */ static void Ins_NPUSHB( TT_ExecContext exc, FT_Long* args ) { FT_UShort L, K; L = (FT_UShort)exc->code[exc->IP + 1]; if ( BOUNDS( L, exc->stackSize + 1 - exc->top ) ) { exc->error = FT_THROW( Stack_Overflow ); return; } for ( K = 1; K <= L; K++ ) args[K - 1] = exc->code[exc->IP + K + 1]; exc->new_top += L; } /************************************************************************** * * NPUSHW[]: PUSH N Words * Opcode range: 0x41 * Stack: --> int32... */ static void Ins_NPUSHW( TT_ExecContext exc, FT_Long* args ) { FT_UShort L, K; L = (FT_UShort)exc->code[exc->IP + 1]; if ( BOUNDS( L, exc->stackSize + 1 - exc->top ) ) { exc->error = FT_THROW( Stack_Overflow ); return; } exc->IP += 2; for ( K = 0; K < L; K++ ) args[K] = GetShortIns( exc ); exc->step_ins = FALSE; exc->new_top += L; } /************************************************************************** * * PUSHB[abc]: PUSH Bytes * Opcode range: 0xB0-0xB7 * Stack: --> uint32... */ static void Ins_PUSHB( TT_ExecContext exc, FT_Long* args ) { FT_UShort L, K; L = (FT_UShort)( exc->opcode - 0xB0 + 1 ); if ( BOUNDS( L, exc->stackSize + 1 - exc->top ) ) { exc->error = FT_THROW( Stack_Overflow ); return; } for ( K = 1; K <= L; K++ ) args[K - 1] = exc->code[exc->IP + K]; } /************************************************************************** * * PUSHW[abc]: PUSH Words * Opcode range: 0xB8-0xBF * Stack: --> int32... */ static void Ins_PUSHW( TT_ExecContext exc, FT_Long* args ) { FT_UShort L, K; L = (FT_UShort)( exc->opcode - 0xB8 + 1 ); if ( BOUNDS( L, exc->stackSize + 1 - exc->top ) ) { exc->error = FT_THROW( Stack_Overflow ); return; } exc->IP++; for ( K = 0; K < L; K++ ) args[K] = GetShortIns( exc ); exc->step_ins = FALSE; } /************************************************************************** * * MANAGING THE GRAPHICS STATE * */ static FT_Bool Ins_SxVTL( TT_ExecContext exc, FT_UShort aIdx1, FT_UShort aIdx2, FT_UnitVector* Vec ) { FT_Long A, B, C; FT_Vector* p1; FT_Vector* p2; FT_Byte opcode = exc->opcode; if ( BOUNDS( aIdx1, exc->zp2.n_points ) || BOUNDS( aIdx2, exc->zp1.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return FAILURE; } p1 = exc->zp1.cur + aIdx2; p2 = exc->zp2.cur + aIdx1; A = SUB_LONG( p1->x, p2->x ); B = SUB_LONG( p1->y, p2->y ); /* If p1 == p2, SPvTL and SFvTL behave the same as */ /* SPvTCA[X] and SFvTCA[X], respectively. */ /* */ /* Confirmed by Greg Hitchcock. */ if ( A == 0 && B == 0 ) { A = 0x4000; opcode = 0; } if ( ( opcode & 1 ) != 0 ) { C = B; /* counter clockwise rotation */ B = A; A = NEG_LONG( C ); } Normalize( A, B, Vec ); return SUCCESS; } /************************************************************************** * * SVTCA[a]: Set (F and P) Vectors to Coordinate Axis * Opcode range: 0x00-0x01 * Stack: --> * * SPvTCA[a]: Set PVector to Coordinate Axis * Opcode range: 0x02-0x03 * Stack: --> * * SFvTCA[a]: Set FVector to Coordinate Axis * Opcode range: 0x04-0x05 * Stack: --> */ static void Ins_SxyTCA( TT_ExecContext exc ) { FT_Short AA, BB; FT_Byte opcode = exc->opcode; AA = (FT_Short)( ( opcode & 1 ) << 14 ); BB = (FT_Short)( AA ^ 0x4000 ); if ( opcode < 4 ) { exc->GS.projVector.x = AA; exc->GS.projVector.y = BB; exc->GS.dualVector.x = AA; exc->GS.dualVector.y = BB; } if ( ( opcode & 2 ) == 0 ) { exc->GS.freeVector.x = AA; exc->GS.freeVector.y = BB; } Compute_Funcs( exc ); } /************************************************************************** * * SPvTL[a]: Set PVector To Line * Opcode range: 0x06-0x07 * Stack: uint32 uint32 --> */ static void Ins_SPVTL( TT_ExecContext exc, FT_Long* args ) { if ( Ins_SxVTL( exc, (FT_UShort)args[1], (FT_UShort)args[0], &exc->GS.projVector ) == SUCCESS ) { exc->GS.dualVector = exc->GS.projVector; Compute_Funcs( exc ); } } /************************************************************************** * * SFvTL[a]: Set FVector To Line * Opcode range: 0x08-0x09 * Stack: uint32 uint32 --> */ static void Ins_SFVTL( TT_ExecContext exc, FT_Long* args ) { if ( Ins_SxVTL( exc, (FT_UShort)args[1], (FT_UShort)args[0], &exc->GS.freeVector ) == SUCCESS ) { Compute_Funcs( exc ); } } /************************************************************************** * * SFvTPv[]: Set FVector To PVector * Opcode range: 0x0E * Stack: --> */ static void Ins_SFVTPV( TT_ExecContext exc ) { exc->GS.freeVector = exc->GS.projVector; Compute_Funcs( exc ); } /************************************************************************** * * SPvFS[]: Set PVector From Stack * Opcode range: 0x0A * Stack: f2.14 f2.14 --> */ static void Ins_SPVFS( TT_ExecContext exc, FT_Long* args ) { FT_Short S; FT_Long X, Y; /* Only use low 16bits, then sign extend */ S = (FT_Short)args[1]; Y = (FT_Long)S; S = (FT_Short)args[0]; X = (FT_Long)S; Normalize( X, Y, &exc->GS.projVector ); exc->GS.dualVector = exc->GS.projVector; Compute_Funcs( exc ); } /************************************************************************** * * SFvFS[]: Set FVector From Stack * Opcode range: 0x0B * Stack: f2.14 f2.14 --> */ static void Ins_SFVFS( TT_ExecContext exc, FT_Long* args ) { FT_Short S; FT_Long X, Y; /* Only use low 16bits, then sign extend */ S = (FT_Short)args[1]; Y = (FT_Long)S; S = (FT_Short)args[0]; X = S; Normalize( X, Y, &exc->GS.freeVector ); Compute_Funcs( exc ); } /************************************************************************** * * GPv[]: Get Projection Vector * Opcode range: 0x0C * Stack: ef2.14 --> ef2.14 */ static void Ins_GPV( TT_ExecContext exc, FT_Long* args ) { args[0] = exc->GS.projVector.x; args[1] = exc->GS.projVector.y; } /************************************************************************** * * GFv[]: Get Freedom Vector * Opcode range: 0x0D * Stack: ef2.14 --> ef2.14 */ static void Ins_GFV( TT_ExecContext exc, FT_Long* args ) { args[0] = exc->GS.freeVector.x; args[1] = exc->GS.freeVector.y; } /************************************************************************** * * SRP0[]: Set Reference Point 0 * Opcode range: 0x10 * Stack: uint32 --> */ static void Ins_SRP0( TT_ExecContext exc, FT_Long* args ) { exc->GS.rp0 = (FT_UShort)args[0]; } /************************************************************************** * * SRP1[]: Set Reference Point 1 * Opcode range: 0x11 * Stack: uint32 --> */ static void Ins_SRP1( TT_ExecContext exc, FT_Long* args ) { exc->GS.rp1 = (FT_UShort)args[0]; } /************************************************************************** * * SRP2[]: Set Reference Point 2 * Opcode range: 0x12 * Stack: uint32 --> */ static void Ins_SRP2( TT_ExecContext exc, FT_Long* args ) { exc->GS.rp2 = (FT_UShort)args[0]; } /************************************************************************** * * SMD[]: Set Minimum Distance * Opcode range: 0x1A * Stack: f26.6 --> */ static void Ins_SMD( TT_ExecContext exc, FT_Long* args ) { exc->GS.minimum_distance = args[0]; } /************************************************************************** * * SCVTCI[]: Set Control Value Table Cut In * Opcode range: 0x1D * Stack: f26.6 --> */ static void Ins_SCVTCI( TT_ExecContext exc, FT_Long* args ) { exc->GS.control_value_cutin = (FT_F26Dot6)args[0]; } /************************************************************************** * * SSWCI[]: Set Single Width Cut In * Opcode range: 0x1E * Stack: f26.6 --> */ static void Ins_SSWCI( TT_ExecContext exc, FT_Long* args ) { exc->GS.single_width_cutin = (FT_F26Dot6)args[0]; } /************************************************************************** * * SSW[]: Set Single Width * Opcode range: 0x1F * Stack: int32? --> */ static void Ins_SSW( TT_ExecContext exc, FT_Long* args ) { exc->GS.single_width_value = FT_MulFix( args[0], exc->tt_metrics.scale ); } /************************************************************************** * * FLIPON[]: Set auto-FLIP to ON * Opcode range: 0x4D * Stack: --> */ static void Ins_FLIPON( TT_ExecContext exc ) { exc->GS.auto_flip = TRUE; } /************************************************************************** * * FLIPOFF[]: Set auto-FLIP to OFF * Opcode range: 0x4E * Stack: --> */ static void Ins_FLIPOFF( TT_ExecContext exc ) { exc->GS.auto_flip = FALSE; } /************************************************************************** * * SANGW[]: Set ANGle Weight * Opcode range: 0x7E * Stack: uint32 --> */ static void Ins_SANGW( void ) { /* instruction not supported anymore */ } /************************************************************************** * * SDB[]: Set Delta Base * Opcode range: 0x5E * Stack: uint32 --> */ static void Ins_SDB( TT_ExecContext exc, FT_Long* args ) { exc->GS.delta_base = (FT_UShort)args[0]; } /************************************************************************** * * SDS[]: Set Delta Shift * Opcode range: 0x5F * Stack: uint32 --> */ static void Ins_SDS( TT_ExecContext exc, FT_Long* args ) { if ( (FT_ULong)args[0] > 6UL ) exc->error = FT_THROW( Bad_Argument ); else exc->GS.delta_shift = (FT_UShort)args[0]; } /************************************************************************** * * RTHG[]: Round To Half Grid * Opcode range: 0x19 * Stack: --> */ static void Ins_RTHG( TT_ExecContext exc ) { exc->GS.round_state = TT_Round_To_Half_Grid; exc->func_round = (TT_Round_Func)Round_To_Half_Grid; } /************************************************************************** * * RTG[]: Round To Grid * Opcode range: 0x18 * Stack: --> */ static void Ins_RTG( TT_ExecContext exc ) { exc->GS.round_state = TT_Round_To_Grid; exc->func_round = (TT_Round_Func)Round_To_Grid; } /************************************************************************** * RTDG[]: Round To Double Grid * Opcode range: 0x3D * Stack: --> */ static void Ins_RTDG( TT_ExecContext exc ) { exc->GS.round_state = TT_Round_To_Double_Grid; exc->func_round = (TT_Round_Func)Round_To_Double_Grid; } /************************************************************************** * RUTG[]: Round Up To Grid * Opcode range: 0x7C * Stack: --> */ static void Ins_RUTG( TT_ExecContext exc ) { exc->GS.round_state = TT_Round_Up_To_Grid; exc->func_round = (TT_Round_Func)Round_Up_To_Grid; } /************************************************************************** * * RDTG[]: Round Down To Grid * Opcode range: 0x7D * Stack: --> */ static void Ins_RDTG( TT_ExecContext exc ) { exc->GS.round_state = TT_Round_Down_To_Grid; exc->func_round = (TT_Round_Func)Round_Down_To_Grid; } /************************************************************************** * * ROFF[]: Round OFF * Opcode range: 0x7A * Stack: --> */ static void Ins_ROFF( TT_ExecContext exc ) { exc->GS.round_state = TT_Round_Off; exc->func_round = (TT_Round_Func)Round_None; } /************************************************************************** * * SROUND[]: Super ROUND * Opcode range: 0x76 * Stack: Eint8 --> */ static void Ins_SROUND( TT_ExecContext exc, FT_Long* args ) { SetSuperRound( exc, 0x4000, args[0] ); exc->GS.round_state = TT_Round_Super; exc->func_round = (TT_Round_Func)Round_Super; } /************************************************************************** * * S45ROUND[]: Super ROUND 45 degrees * Opcode range: 0x77 * Stack: uint32 --> */ static void Ins_S45ROUND( TT_ExecContext exc, FT_Long* args ) { SetSuperRound( exc, 0x2D41, args[0] ); exc->GS.round_state = TT_Round_Super_45; exc->func_round = (TT_Round_Func)Round_Super_45; } /************************************************************************** * * GC[a]: Get Coordinate projected onto * Opcode range: 0x46-0x47 * Stack: uint32 --> f26.6 * * XXX: UNDOCUMENTED: Measures from the original glyph must be taken * along the dual projection vector! */ static void Ins_GC( TT_ExecContext exc, FT_Long* args ) { FT_ULong L; FT_F26Dot6 R; L = (FT_ULong)args[0]; if ( BOUNDSL( L, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); R = 0; } else { if ( exc->opcode & 1 ) R = FAST_DUALPROJ( &exc->zp2.org[L] ); else R = FAST_PROJECT( &exc->zp2.cur[L] ); } args[0] = R; } /************************************************************************** * * SCFS[]: Set Coordinate From Stack * Opcode range: 0x48 * Stack: f26.6 uint32 --> * * Formula: * * OA := OA + ( value - OA.p )/( f.p ) * f */ static void Ins_SCFS( TT_ExecContext exc, FT_Long* args ) { FT_Long K; FT_UShort L; L = (FT_UShort)args[0]; if ( BOUNDS( L, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } K = FAST_PROJECT( &exc->zp2.cur[L] ); exc->func_move( exc, &exc->zp2, L, SUB_LONG( args[1], K ) ); /* UNDOCUMENTED! The MS rasterizer does that with */ /* twilight points (confirmed by Greg Hitchcock) */ if ( exc->GS.gep2 == 0 ) exc->zp2.org[L] = exc->zp2.cur[L]; } /************************************************************************** * * MD[a]: Measure Distance * Opcode range: 0x49-0x4A * Stack: uint32 uint32 --> f26.6 * * XXX: UNDOCUMENTED: Measure taken in the original glyph must be along * the dual projection vector. * * XXX: UNDOCUMENTED: Flag attributes are inverted! * 0 => measure distance in original outline * 1 => measure distance in grid-fitted outline * * XXX: UNDOCUMENTED: `zp0 - zp1', and not `zp2 - zp1! */ static void Ins_MD( TT_ExecContext exc, FT_Long* args ) { FT_UShort K, L; FT_F26Dot6 D; K = (FT_UShort)args[1]; L = (FT_UShort)args[0]; if ( BOUNDS( L, exc->zp0.n_points ) || BOUNDS( K, exc->zp1.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); D = 0; } else { if ( exc->opcode & 1 ) D = PROJECT( exc->zp0.cur + L, exc->zp1.cur + K ); else { /* XXX: UNDOCUMENTED: twilight zone special case */ if ( exc->GS.gep0 == 0 || exc->GS.gep1 == 0 ) { FT_Vector* vec1 = exc->zp0.org + L; FT_Vector* vec2 = exc->zp1.org + K; D = DUALPROJ( vec1, vec2 ); } else { FT_Vector* vec1 = exc->zp0.orus + L; FT_Vector* vec2 = exc->zp1.orus + K; if ( exc->metrics.x_scale == exc->metrics.y_scale ) { /* this should be faster */ D = DUALPROJ( vec1, vec2 ); D = FT_MulFix( D, exc->metrics.x_scale ); } else { FT_Vector vec; vec.x = FT_MulFix( vec1->x - vec2->x, exc->metrics.x_scale ); vec.y = FT_MulFix( vec1->y - vec2->y, exc->metrics.y_scale ); D = FAST_DUALPROJ( &vec ); } } } } #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* Disable Type 2 Vacuform Rounds - e.g. Arial Narrow */ if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && FT_ABS( D ) == 64 ) D += 1; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ args[0] = D; } /************************************************************************** * * SDPvTL[a]: Set Dual PVector to Line * Opcode range: 0x86-0x87 * Stack: uint32 uint32 --> */ static void Ins_SDPVTL( TT_ExecContext exc, FT_Long* args ) { FT_Long A, B, C; FT_UShort p1, p2; /* was FT_Int in pas type ERROR */ FT_Byte opcode = exc->opcode; p1 = (FT_UShort)args[1]; p2 = (FT_UShort)args[0]; if ( BOUNDS( p2, exc->zp1.n_points ) || BOUNDS( p1, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } { FT_Vector* v1 = exc->zp1.org + p2; FT_Vector* v2 = exc->zp2.org + p1; A = SUB_LONG( v1->x, v2->x ); B = SUB_LONG( v1->y, v2->y ); /* If v1 == v2, SDPvTL behaves the same as */ /* SVTCA[X], respectively. */ /* */ /* Confirmed by Greg Hitchcock. */ if ( A == 0 && B == 0 ) { A = 0x4000; opcode = 0; } } if ( ( opcode & 1 ) != 0 ) { C = B; /* counter clockwise rotation */ B = A; A = NEG_LONG( C ); } Normalize( A, B, &exc->GS.dualVector ); { FT_Vector* v1 = exc->zp1.cur + p2; FT_Vector* v2 = exc->zp2.cur + p1; A = SUB_LONG( v1->x, v2->x ); B = SUB_LONG( v1->y, v2->y ); if ( A == 0 && B == 0 ) { A = 0x4000; opcode = 0; } } if ( ( opcode & 1 ) != 0 ) { C = B; /* counter clockwise rotation */ B = A; A = NEG_LONG( C ); } Normalize( A, B, &exc->GS.projVector ); Compute_Funcs( exc ); } /************************************************************************** * * SZP0[]: Set Zone Pointer 0 * Opcode range: 0x13 * Stack: uint32 --> */ static void Ins_SZP0( TT_ExecContext exc, FT_Long* args ) { switch ( (FT_Int)args[0] ) { case 0: exc->zp0 = exc->twilight; break; case 1: exc->zp0 = exc->pts; break; default: if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } exc->GS.gep0 = (FT_UShort)args[0]; } /************************************************************************** * * SZP1[]: Set Zone Pointer 1 * Opcode range: 0x14 * Stack: uint32 --> */ static void Ins_SZP1( TT_ExecContext exc, FT_Long* args ) { switch ( (FT_Int)args[0] ) { case 0: exc->zp1 = exc->twilight; break; case 1: exc->zp1 = exc->pts; break; default: if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } exc->GS.gep1 = (FT_UShort)args[0]; } /************************************************************************** * * SZP2[]: Set Zone Pointer 2 * Opcode range: 0x15 * Stack: uint32 --> */ static void Ins_SZP2( TT_ExecContext exc, FT_Long* args ) { switch ( (FT_Int)args[0] ) { case 0: exc->zp2 = exc->twilight; break; case 1: exc->zp2 = exc->pts; break; default: if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } exc->GS.gep2 = (FT_UShort)args[0]; } /************************************************************************** * * SZPS[]: Set Zone PointerS * Opcode range: 0x16 * Stack: uint32 --> */ static void Ins_SZPS( TT_ExecContext exc, FT_Long* args ) { switch ( (FT_Int)args[0] ) { case 0: exc->zp0 = exc->twilight; break; case 1: exc->zp0 = exc->pts; break; default: if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } exc->zp1 = exc->zp0; exc->zp2 = exc->zp0; exc->GS.gep0 = (FT_UShort)args[0]; exc->GS.gep1 = (FT_UShort)args[0]; exc->GS.gep2 = (FT_UShort)args[0]; } /************************************************************************** * * INSTCTRL[]: INSTruction ConTRoL * Opcode range: 0x8E * Stack: int32 int32 --> */ static void Ins_INSTCTRL( TT_ExecContext exc, FT_Long* args ) { FT_ULong K, L, Kf; K = (FT_ULong)args[1]; L = (FT_ULong)args[0]; /* selector values cannot be `OR'ed; */ /* they are indices starting with index 1, not flags */ if ( K < 1 || K > 3 ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } /* convert index to flag value */ Kf = 1 << ( K - 1 ); if ( L != 0 ) { /* arguments to selectors look like flag values */ if ( L != Kf ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } } exc->GS.instruct_control &= ~(FT_Byte)Kf; exc->GS.instruct_control |= (FT_Byte)L; if ( K == 3 ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* INSTCTRL modifying flag 3 also has an effect */ /* outside of the CVT program */ if ( SUBPIXEL_HINTING_INFINALITY ) exc->ignore_x_mode = FT_BOOL( L == 4 ); #endif #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* Native ClearType fonts sign a waiver that turns off all backward */ /* compatibility hacks and lets them program points to the grid like */ /* it's 1996. They might sign a waiver for just one glyph, though. */ if ( SUBPIXEL_HINTING_MINIMAL ) exc->backward_compatibility = !FT_BOOL( L == 4 ); #endif } } /************************************************************************** * * SCANCTRL[]: SCAN ConTRoL * Opcode range: 0x85 * Stack: uint32? --> */ static void Ins_SCANCTRL( TT_ExecContext exc, FT_Long* args ) { FT_Int A; /* Get Threshold */ A = (FT_Int)( args[0] & 0xFF ); if ( A == 0xFF ) { exc->GS.scan_control = TRUE; return; } else if ( A == 0 ) { exc->GS.scan_control = FALSE; return; } if ( ( args[0] & 0x100 ) != 0 && exc->tt_metrics.ppem <= A ) exc->GS.scan_control = TRUE; if ( ( args[0] & 0x200 ) != 0 && exc->tt_metrics.rotated ) exc->GS.scan_control = TRUE; if ( ( args[0] & 0x400 ) != 0 && exc->tt_metrics.stretched ) exc->GS.scan_control = TRUE; if ( ( args[0] & 0x800 ) != 0 && exc->tt_metrics.ppem > A ) exc->GS.scan_control = FALSE; if ( ( args[0] & 0x1000 ) != 0 && exc->tt_metrics.rotated ) exc->GS.scan_control = FALSE; if ( ( args[0] & 0x2000 ) != 0 && exc->tt_metrics.stretched ) exc->GS.scan_control = FALSE; } /************************************************************************** * * SCANTYPE[]: SCAN TYPE * Opcode range: 0x8D * Stack: uint16 --> */ static void Ins_SCANTYPE( TT_ExecContext exc, FT_Long* args ) { if ( args[0] >= 0 ) exc->GS.scan_type = (FT_Int)args[0] & 0xFFFF; } /************************************************************************** * * MANAGING OUTLINES * */ /************************************************************************** * * FLIPPT[]: FLIP PoinT * Opcode range: 0x80 * Stack: uint32... --> */ static void Ins_FLIPPT( TT_ExecContext exc ) { FT_UShort point; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* See `ttinterp.h' for details on backward compatibility mode. */ if ( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility && exc->iupx_called && exc->iupy_called ) goto Fail; #endif if ( exc->top < exc->GS.loop ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Too_Few_Arguments ); goto Fail; } while ( exc->GS.loop > 0 ) { exc->args--; point = (FT_UShort)exc->stack[exc->args]; if ( BOUNDS( point, exc->pts.n_points ) ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Invalid_Reference ); return; } } else exc->pts.tags[point] ^= FT_CURVE_TAG_ON; exc->GS.loop--; } Fail: exc->GS.loop = 1; exc->new_top = exc->args; } /************************************************************************** * * FLIPRGON[]: FLIP RanGe ON * Opcode range: 0x81 * Stack: uint32 uint32 --> */ static void Ins_FLIPRGON( TT_ExecContext exc, FT_Long* args ) { FT_UShort I, K, L; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* See `ttinterp.h' for details on backward compatibility mode. */ if ( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility && exc->iupx_called && exc->iupy_called ) return; #endif K = (FT_UShort)args[1]; L = (FT_UShort)args[0]; if ( BOUNDS( K, exc->pts.n_points ) || BOUNDS( L, exc->pts.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } for ( I = L; I <= K; I++ ) exc->pts.tags[I] |= FT_CURVE_TAG_ON; } /************************************************************************** * * FLIPRGOFF: FLIP RanGe OFF * Opcode range: 0x82 * Stack: uint32 uint32 --> */ static void Ins_FLIPRGOFF( TT_ExecContext exc, FT_Long* args ) { FT_UShort I, K, L; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* See `ttinterp.h' for details on backward compatibility mode. */ if ( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility && exc->iupx_called && exc->iupy_called ) return; #endif K = (FT_UShort)args[1]; L = (FT_UShort)args[0]; if ( BOUNDS( K, exc->pts.n_points ) || BOUNDS( L, exc->pts.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } for ( I = L; I <= K; I++ ) exc->pts.tags[I] &= ~FT_CURVE_TAG_ON; } static FT_Bool Compute_Point_Displacement( TT_ExecContext exc, FT_F26Dot6* x, FT_F26Dot6* y, TT_GlyphZone zone, FT_UShort* refp ) { TT_GlyphZoneRec zp; FT_UShort p; FT_F26Dot6 d; if ( exc->opcode & 1 ) { zp = exc->zp0; p = exc->GS.rp1; } else { zp = exc->zp1; p = exc->GS.rp2; } if ( BOUNDS( p, zp.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); *refp = 0; return FAILURE; } *zone = zp; *refp = p; d = PROJECT( zp.cur + p, zp.org + p ); *x = FT_MulDiv( d, (FT_Long)exc->GS.freeVector.x, exc->F_dot_P ); *y = FT_MulDiv( d, (FT_Long)exc->GS.freeVector.y, exc->F_dot_P ); return SUCCESS; } /* See `ttinterp.h' for details on backward compatibility mode. */ static void Move_Zp2_Point( TT_ExecContext exc, FT_UShort point, FT_F26Dot6 dx, FT_F26Dot6 dy, FT_Bool touch ) { if ( exc->GS.freeVector.x != 0 ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL if ( !( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility ) ) #endif exc->zp2.cur[point].x = ADD_LONG( exc->zp2.cur[point].x, dx ); if ( touch ) exc->zp2.tags[point] |= FT_CURVE_TAG_TOUCH_X; } if ( exc->GS.freeVector.y != 0 ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL if ( !( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility && exc->iupx_called && exc->iupy_called ) ) #endif exc->zp2.cur[point].y = ADD_LONG( exc->zp2.cur[point].y, dy ); if ( touch ) exc->zp2.tags[point] |= FT_CURVE_TAG_TOUCH_Y; } } /************************************************************************** * * SHP[a]: SHift Point by the last point * Opcode range: 0x32-0x33 * Stack: uint32... --> */ static void Ins_SHP( TT_ExecContext exc ) { TT_GlyphZoneRec zp; FT_UShort refp; FT_F26Dot6 dx, dy; FT_UShort point; if ( exc->top < exc->GS.loop ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } if ( Compute_Point_Displacement( exc, &dx, &dy, &zp, &refp ) ) return; while ( exc->GS.loop > 0 ) { exc->args--; point = (FT_UShort)exc->stack[exc->args]; if ( BOUNDS( point, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Invalid_Reference ); return; } } else #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* doesn't follow Cleartype spec but produces better result */ if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode ) Move_Zp2_Point( exc, point, 0, dy, TRUE ); else #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ Move_Zp2_Point( exc, point, dx, dy, TRUE ); exc->GS.loop--; } Fail: exc->GS.loop = 1; exc->new_top = exc->args; } /************************************************************************** * * SHC[a]: SHift Contour * Opcode range: 0x34-35 * Stack: uint32 --> * * UNDOCUMENTED: According to Greg Hitchcock, there is one (virtual) * contour in the twilight zone, namely contour number * zero which includes all points of it. */ static void Ins_SHC( TT_ExecContext exc, FT_Long* args ) { TT_GlyphZoneRec zp; FT_UShort refp; FT_F26Dot6 dx, dy; FT_Short contour, bounds; FT_UShort start, limit, i; contour = (FT_Short)args[0]; bounds = ( exc->GS.gep2 == 0 ) ? 1 : exc->zp2.n_contours; if ( BOUNDS( contour, bounds ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } if ( Compute_Point_Displacement( exc, &dx, &dy, &zp, &refp ) ) return; if ( contour == 0 ) start = 0; else start = (FT_UShort)( exc->zp2.contours[contour - 1] + 1 - exc->zp2.first_point ); /* we use the number of points if in the twilight zone */ if ( exc->GS.gep2 == 0 ) limit = exc->zp2.n_points; else limit = (FT_UShort)( exc->zp2.contours[contour] - exc->zp2.first_point + 1 ); for ( i = start; i < limit; i++ ) { if ( zp.cur != exc->zp2.cur || refp != i ) Move_Zp2_Point( exc, i, dx, dy, TRUE ); } } /************************************************************************** * * SHZ[a]: SHift Zone * Opcode range: 0x36-37 * Stack: uint32 --> */ static void Ins_SHZ( TT_ExecContext exc, FT_Long* args ) { TT_GlyphZoneRec zp; FT_UShort refp; FT_F26Dot6 dx, dy; FT_UShort limit, i; if ( BOUNDS( args[0], 2 ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } if ( Compute_Point_Displacement( exc, &dx, &dy, &zp, &refp ) ) return; /* XXX: UNDOCUMENTED! SHZ doesn't move the phantom points. */ /* Twilight zone has no real contours, so use `n_points'. */ /* Normal zone's `n_points' includes phantoms, so must */ /* use end of last contour. */ if ( exc->GS.gep2 == 0 ) limit = (FT_UShort)exc->zp2.n_points; else if ( exc->GS.gep2 == 1 && exc->zp2.n_contours > 0 ) limit = (FT_UShort)( exc->zp2.contours[exc->zp2.n_contours - 1] + 1 ); else limit = 0; /* XXX: UNDOCUMENTED! SHZ doesn't touch the points */ for ( i = 0; i < limit; i++ ) { if ( zp.cur != exc->zp2.cur || refp != i ) Move_Zp2_Point( exc, i, dx, dy, FALSE ); } } /************************************************************************** * * SHPIX[]: SHift points by a PIXel amount * Opcode range: 0x38 * Stack: f26.6 uint32... --> */ static void Ins_SHPIX( TT_ExecContext exc, FT_Long* args ) { FT_F26Dot6 dx, dy; FT_UShort point; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY FT_Int B1, B2; #endif #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL FT_Bool in_twilight = FT_BOOL( exc->GS.gep0 == 0 || exc->GS.gep1 == 0 || exc->GS.gep2 == 0 ); #endif if ( exc->top < exc->GS.loop + 1 ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } dx = TT_MulFix14( args[0], exc->GS.freeVector.x ); dy = TT_MulFix14( args[0], exc->GS.freeVector.y ); while ( exc->GS.loop > 0 ) { exc->args--; point = (FT_UShort)exc->stack[exc->args]; if ( BOUNDS( point, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Invalid_Reference ); return; } } else #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY ) { /* If not using ignore_x_mode rendering, allow ZP2 move. */ /* If inline deltas aren't allowed, skip ZP2 move. */ /* If using ignore_x_mode rendering, allow ZP2 point move if: */ /* - freedom vector is y and sph_compatibility_mode is off */ /* - the glyph is composite and the move is in the Y direction */ /* - the glyph is specifically set to allow SHPIX moves */ /* - the move is on a previously Y-touched point */ if ( exc->ignore_x_mode ) { /* save point for later comparison */ if ( exc->GS.freeVector.y != 0 ) B1 = exc->zp2.cur[point].y; else B1 = exc->zp2.cur[point].x; if ( !exc->face->sph_compatibility_mode && exc->GS.freeVector.y != 0 ) { Move_Zp2_Point( exc, point, dx, dy, TRUE ); /* save new point */ if ( exc->GS.freeVector.y != 0 ) { B2 = exc->zp2.cur[point].y; /* reverse any disallowed moves */ if ( ( exc->sph_tweak_flags & SPH_TWEAK_SKIP_NONPIXEL_Y_MOVES ) && ( B1 & 63 ) != 0 && ( B2 & 63 ) != 0 && B1 != B2 ) Move_Zp2_Point( exc, point, NEG_LONG( dx ), NEG_LONG( dy ), TRUE ); } } else if ( exc->face->sph_compatibility_mode ) { if ( exc->sph_tweak_flags & SPH_TWEAK_ROUND_NONPIXEL_Y_MOVES ) { dx = FT_PIX_ROUND( B1 + dx ) - B1; dy = FT_PIX_ROUND( B1 + dy ) - B1; } /* skip post-iup deltas */ if ( exc->iup_called && ( ( exc->sph_in_func_flags & SPH_FDEF_INLINE_DELTA_1 ) || ( exc->sph_in_func_flags & SPH_FDEF_INLINE_DELTA_2 ) ) ) goto Skip; if ( !( exc->sph_tweak_flags & SPH_TWEAK_ALWAYS_SKIP_DELTAP ) && ( ( exc->is_composite && exc->GS.freeVector.y != 0 ) || ( exc->zp2.tags[point] & FT_CURVE_TAG_TOUCH_Y ) || ( exc->sph_tweak_flags & SPH_TWEAK_DO_SHPIX ) ) ) Move_Zp2_Point( exc, point, 0, dy, TRUE ); /* save new point */ if ( exc->GS.freeVector.y != 0 ) { B2 = exc->zp2.cur[point].y; /* reverse any disallowed moves */ if ( ( B1 & 63 ) == 0 && ( B2 & 63 ) != 0 && B1 != B2 ) Move_Zp2_Point( exc, point, 0, NEG_LONG( dy ), TRUE ); } } else if ( exc->sph_in_func_flags & SPH_FDEF_TYPEMAN_DIAGENDCTRL ) Move_Zp2_Point( exc, point, dx, dy, TRUE ); } else Move_Zp2_Point( exc, point, dx, dy, TRUE ); } else #endif #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL if ( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility ) { /* Special case: allow SHPIX to move points in the twilight zone. */ /* Otherwise, treat SHPIX the same as DELTAP. Unbreaks various */ /* fonts such as older versions of Rokkitt and DTL Argo T Light */ /* that would glitch severely after calling ALIGNRP after a */ /* blocked SHPIX. */ if ( in_twilight || ( !( exc->iupx_called && exc->iupy_called ) && ( ( exc->is_composite && exc->GS.freeVector.y != 0 ) || ( exc->zp2.tags[point] & FT_CURVE_TAG_TOUCH_Y ) ) ) ) Move_Zp2_Point( exc, point, 0, dy, TRUE ); } else #endif Move_Zp2_Point( exc, point, dx, dy, TRUE ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY Skip: #endif exc->GS.loop--; } Fail: exc->GS.loop = 1; exc->new_top = exc->args; } /************************************************************************** * * MSIRP[a]: Move Stack Indirect Relative Position * Opcode range: 0x3A-0x3B * Stack: f26.6 uint32 --> */ static void Ins_MSIRP( TT_ExecContext exc, FT_Long* args ) { FT_UShort point = 0; FT_F26Dot6 distance; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY FT_F26Dot6 control_value_cutin = 0; FT_F26Dot6 delta; if ( SUBPIXEL_HINTING_INFINALITY ) { control_value_cutin = exc->GS.control_value_cutin; if ( exc->ignore_x_mode && exc->GS.freeVector.x != 0 && !( exc->sph_tweak_flags & SPH_TWEAK_NORMAL_ROUND ) ) control_value_cutin = 0; } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ point = (FT_UShort)args[0]; if ( BOUNDS( point, exc->zp1.n_points ) || BOUNDS( exc->GS.rp0, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } /* UNDOCUMENTED! The MS rasterizer does that with */ /* twilight points (confirmed by Greg Hitchcock) */ if ( exc->GS.gep1 == 0 ) { exc->zp1.org[point] = exc->zp0.org[exc->GS.rp0]; exc->func_move_orig( exc, &exc->zp1, point, args[1] ); exc->zp1.cur[point] = exc->zp1.org[point]; } distance = PROJECT( exc->zp1.cur + point, exc->zp0.cur + exc->GS.rp0 ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY delta = SUB_LONG( distance, args[1] ); if ( delta < 0 ) delta = NEG_LONG( delta ); /* subpixel hinting - make MSIRP respect CVT cut-in; */ if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 && delta >= control_value_cutin ) distance = args[1]; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ exc->func_move( exc, &exc->zp1, point, SUB_LONG( args[1], distance ) ); exc->GS.rp1 = exc->GS.rp0; exc->GS.rp2 = point; if ( ( exc->opcode & 1 ) != 0 ) exc->GS.rp0 = point; } /************************************************************************** * * MDAP[a]: Move Direct Absolute Point * Opcode range: 0x2E-0x2F * Stack: uint32 --> */ static void Ins_MDAP( TT_ExecContext exc, FT_Long* args ) { FT_UShort point; FT_F26Dot6 cur_dist; FT_F26Dot6 distance; point = (FT_UShort)args[0]; if ( BOUNDS( point, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } if ( ( exc->opcode & 1 ) != 0 ) { cur_dist = FAST_PROJECT( &exc->zp0.cur[point] ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 ) distance = SUB_LONG( Round_None( exc, cur_dist, exc->tt_metrics.compensations[0] ), cur_dist ); else #endif distance = SUB_LONG( exc->func_round( exc, cur_dist, exc->tt_metrics.compensations[0] ), cur_dist ); } else distance = 0; exc->func_move( exc, &exc->zp0, point, distance ); exc->GS.rp0 = point; exc->GS.rp1 = point; } /************************************************************************** * * MIAP[a]: Move Indirect Absolute Point * Opcode range: 0x3E-0x3F * Stack: uint32 uint32 --> */ static void Ins_MIAP( TT_ExecContext exc, FT_Long* args ) { FT_ULong cvtEntry; FT_UShort point; FT_F26Dot6 distance; FT_F26Dot6 org_dist; FT_F26Dot6 control_value_cutin; control_value_cutin = exc->GS.control_value_cutin; cvtEntry = (FT_ULong)args[1]; point = (FT_UShort)args[0]; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 && exc->GS.freeVector.y == 0 && !( exc->sph_tweak_flags & SPH_TWEAK_NORMAL_ROUND ) ) control_value_cutin = 0; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ if ( BOUNDS( point, exc->zp0.n_points ) || BOUNDSL( cvtEntry, exc->cvtSize ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } /* UNDOCUMENTED! */ /* */ /* The behaviour of an MIAP instruction is quite different when used */ /* in the twilight zone. */ /* */ /* First, no control value cut-in test is performed as it would fail */ /* anyway. Second, the original point, i.e. (org_x,org_y) of */ /* zp0.point, is set to the absolute, unrounded distance found in the */ /* CVT. */ /* */ /* This is used in the CVT programs of the Microsoft fonts Arial, */ /* Times, etc., in order to re-adjust some key font heights. It */ /* allows the use of the IP instruction in the twilight zone, which */ /* otherwise would be invalid according to the specification. */ /* */ /* We implement it with a special sequence for the twilight zone. */ /* This is a bad hack, but it seems to work. */ /* */ /* Confirmed by Greg Hitchcock. */ distance = exc->func_read_cvt( exc, cvtEntry ); if ( exc->GS.gep0 == 0 ) /* If in twilight zone */ { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* Only adjust if not in sph_compatibility_mode or ignore_x_mode. */ /* Determined via experimentation and may be incorrect... */ if ( !( SUBPIXEL_HINTING_INFINALITY && ( exc->ignore_x_mode && exc->face->sph_compatibility_mode ) ) ) #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ exc->zp0.org[point].x = TT_MulFix14( distance, exc->GS.freeVector.x ); exc->zp0.org[point].y = TT_MulFix14( distance, exc->GS.freeVector.y ), exc->zp0.cur[point] = exc->zp0.org[point]; } #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && ( exc->sph_tweak_flags & SPH_TWEAK_MIAP_HACK ) && distance > 0 && exc->GS.freeVector.y != 0 ) distance = 0; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ org_dist = FAST_PROJECT( &exc->zp0.cur[point] ); if ( ( exc->opcode & 1 ) != 0 ) /* rounding and control cut-in flag */ { FT_F26Dot6 delta; delta = SUB_LONG( distance, org_dist ); if ( delta < 0 ) delta = NEG_LONG( delta ); if ( delta > control_value_cutin ) distance = org_dist; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 ) distance = Round_None( exc, distance, exc->tt_metrics.compensations[0] ); else #endif distance = exc->func_round( exc, distance, exc->tt_metrics.compensations[0] ); } exc->func_move( exc, &exc->zp0, point, SUB_LONG( distance, org_dist ) ); Fail: exc->GS.rp0 = point; exc->GS.rp1 = point; } /************************************************************************** * * MDRP[abcde]: Move Direct Relative Point * Opcode range: 0xC0-0xDF * Stack: uint32 --> */ static void Ins_MDRP( TT_ExecContext exc, FT_Long* args ) { FT_UShort point = 0; FT_F26Dot6 org_dist, distance, minimum_distance; minimum_distance = exc->GS.minimum_distance; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 && !( exc->sph_tweak_flags & SPH_TWEAK_NORMAL_ROUND ) ) minimum_distance = 0; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ point = (FT_UShort)args[0]; if ( BOUNDS( point, exc->zp1.n_points ) || BOUNDS( exc->GS.rp0, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } /* XXX: Is there some undocumented feature while in the */ /* twilight zone? */ /* XXX: UNDOCUMENTED: twilight zone special case */ if ( exc->GS.gep0 == 0 || exc->GS.gep1 == 0 ) { FT_Vector* vec1 = &exc->zp1.org[point]; FT_Vector* vec2 = &exc->zp0.org[exc->GS.rp0]; org_dist = DUALPROJ( vec1, vec2 ); } else { FT_Vector* vec1 = &exc->zp1.orus[point]; FT_Vector* vec2 = &exc->zp0.orus[exc->GS.rp0]; if ( exc->metrics.x_scale == exc->metrics.y_scale ) { /* this should be faster */ org_dist = DUALPROJ( vec1, vec2 ); org_dist = FT_MulFix( org_dist, exc->metrics.x_scale ); } else { FT_Vector vec; vec.x = FT_MulFix( SUB_LONG( vec1->x, vec2->x ), exc->metrics.x_scale ); vec.y = FT_MulFix( SUB_LONG( vec1->y, vec2->y ), exc->metrics.y_scale ); org_dist = FAST_DUALPROJ( &vec ); } } /* single width cut-in test */ /* |org_dist - single_width_value| < single_width_cutin */ if ( exc->GS.single_width_cutin > 0 && org_dist < exc->GS.single_width_value + exc->GS.single_width_cutin && org_dist > exc->GS.single_width_value - exc->GS.single_width_cutin ) { if ( org_dist >= 0 ) org_dist = exc->GS.single_width_value; else org_dist = -exc->GS.single_width_value; } /* round flag */ if ( ( exc->opcode & 4 ) != 0 ) { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 ) distance = Round_None( exc, org_dist, exc->tt_metrics.compensations[exc->opcode & 3] ); else #endif distance = exc->func_round( exc, org_dist, exc->tt_metrics.compensations[exc->opcode & 3] ); } else distance = Round_None( exc, org_dist, exc->tt_metrics.compensations[exc->opcode & 3] ); /* minimum distance flag */ if ( ( exc->opcode & 8 ) != 0 ) { if ( org_dist >= 0 ) { if ( distance < minimum_distance ) distance = minimum_distance; } else { if ( distance > NEG_LONG( minimum_distance ) ) distance = NEG_LONG( minimum_distance ); } } /* now move the point */ org_dist = PROJECT( exc->zp1.cur + point, exc->zp0.cur + exc->GS.rp0 ); exc->func_move( exc, &exc->zp1, point, SUB_LONG( distance, org_dist ) ); Fail: exc->GS.rp1 = exc->GS.rp0; exc->GS.rp2 = point; if ( ( exc->opcode & 16 ) != 0 ) exc->GS.rp0 = point; } /************************************************************************** * * MIRP[abcde]: Move Indirect Relative Point * Opcode range: 0xE0-0xFF * Stack: int32? uint32 --> */ static void Ins_MIRP( TT_ExecContext exc, FT_Long* args ) { FT_UShort point; FT_ULong cvtEntry; FT_F26Dot6 cvt_dist, distance, cur_dist, org_dist, control_value_cutin, minimum_distance; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY FT_Int B1 = 0; /* pacify compiler */ FT_Int B2 = 0; FT_Bool reverse_move = FALSE; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ FT_F26Dot6 delta; minimum_distance = exc->GS.minimum_distance; control_value_cutin = exc->GS.control_value_cutin; point = (FT_UShort)args[0]; cvtEntry = (FT_ULong)( ADD_LONG( args[1], 1 ) ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.x != 0 && !( exc->sph_tweak_flags & SPH_TWEAK_NORMAL_ROUND ) ) control_value_cutin = minimum_distance = 0; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ /* XXX: UNDOCUMENTED! cvt[-1] = 0 always */ if ( BOUNDS( point, exc->zp1.n_points ) || BOUNDSL( cvtEntry, exc->cvtSize + 1 ) || BOUNDS( exc->GS.rp0, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } if ( !cvtEntry ) cvt_dist = 0; else cvt_dist = exc->func_read_cvt( exc, cvtEntry - 1 ); /* single width test */ delta = SUB_LONG( cvt_dist, exc->GS.single_width_value ); if ( delta < 0 ) delta = NEG_LONG( delta ); if ( delta < exc->GS.single_width_cutin ) { if ( cvt_dist >= 0 ) cvt_dist = exc->GS.single_width_value; else cvt_dist = -exc->GS.single_width_value; } /* UNDOCUMENTED! The MS rasterizer does that with */ /* twilight points (confirmed by Greg Hitchcock) */ if ( exc->GS.gep1 == 0 ) { exc->zp1.org[point].x = exc->zp0.org[exc->GS.rp0].x + TT_MulFix14( cvt_dist, exc->GS.freeVector.x ); exc->zp1.org[point].y = exc->zp0.org[exc->GS.rp0].y + TT_MulFix14( cvt_dist, exc->GS.freeVector.y ); exc->zp1.cur[point] = exc->zp1.org[point]; } org_dist = DUALPROJ( &exc->zp1.org[point], &exc->zp0.org[exc->GS.rp0] ); cur_dist = PROJECT ( &exc->zp1.cur[point], &exc->zp0.cur[exc->GS.rp0] ); /* auto-flip test */ if ( exc->GS.auto_flip ) { if ( ( org_dist ^ cvt_dist ) < 0 ) cvt_dist = NEG_LONG( cvt_dist ); } #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.freeVector.y != 0 && ( exc->sph_tweak_flags & SPH_TWEAK_TIMES_NEW_ROMAN_HACK ) ) { if ( cur_dist < -64 ) cvt_dist -= 16; else if ( cur_dist > 64 && cur_dist < 84 ) cvt_dist += 32; } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ /* control value cut-in and round */ if ( ( exc->opcode & 4 ) != 0 ) { /* XXX: UNDOCUMENTED! Only perform cut-in test when both points */ /* refer to the same zone. */ if ( exc->GS.gep0 == exc->GS.gep1 ) { /* XXX: According to Greg Hitchcock, the following wording is */ /* the right one: */ /* */ /* When the absolute difference between the value in */ /* the table [CVT] and the measurement directly from */ /* the outline is _greater_ than the cut_in value, the */ /* outline measurement is used. */ /* */ /* This is from `instgly.doc'. The description in */ /* `ttinst2.doc', version 1.66, is thus incorrect since */ /* it implies `>=' instead of `>'. */ delta = SUB_LONG( cvt_dist, org_dist ); if ( delta < 0 ) delta = NEG_LONG( delta ); if ( delta > control_value_cutin ) cvt_dist = org_dist; } distance = exc->func_round( exc, cvt_dist, exc->tt_metrics.compensations[exc->opcode & 3] ); } else { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /* do cvt cut-in always in MIRP for sph */ if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->GS.gep0 == exc->GS.gep1 ) { delta = SUB_LONG( cvt_dist, org_dist ); if ( delta < 0 ) delta = NEG_LONG( delta ); if ( delta > control_value_cutin ) cvt_dist = org_dist; } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ distance = Round_None( exc, cvt_dist, exc->tt_metrics.compensations[exc->opcode & 3] ); } /* minimum distance test */ if ( ( exc->opcode & 8 ) != 0 ) { if ( org_dist >= 0 ) { if ( distance < minimum_distance ) distance = minimum_distance; } else { if ( distance > NEG_LONG( minimum_distance ) ) distance = NEG_LONG( minimum_distance ); } } #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY ) { B1 = exc->zp1.cur[point].y; /* Round moves if necessary */ if ( exc->ignore_x_mode && exc->GS.freeVector.y != 0 && ( exc->sph_tweak_flags & SPH_TWEAK_ROUND_NONPIXEL_Y_MOVES ) ) distance = FT_PIX_ROUND( B1 + distance - cur_dist ) - B1 + cur_dist; if ( exc->ignore_x_mode && exc->GS.freeVector.y != 0 && ( exc->opcode & 16 ) == 0 && ( exc->opcode & 8 ) == 0 && ( exc->sph_tweak_flags & SPH_TWEAK_COURIER_NEW_2_HACK ) ) distance += 64; } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ exc->func_move( exc, &exc->zp1, point, SUB_LONG( distance, cur_dist ) ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY ) { B2 = exc->zp1.cur[point].y; /* Reverse move if necessary */ if ( exc->ignore_x_mode ) { if ( exc->face->sph_compatibility_mode && exc->GS.freeVector.y != 0 && ( B1 & 63 ) == 0 && ( B2 & 63 ) != 0 ) reverse_move = TRUE; if ( ( exc->sph_tweak_flags & SPH_TWEAK_SKIP_NONPIXEL_Y_MOVES ) && exc->GS.freeVector.y != 0 && ( B2 & 63 ) != 0 && ( B1 & 63 ) != 0 ) reverse_move = TRUE; } if ( reverse_move ) exc->func_move( exc, &exc->zp1, point, SUB_LONG( cur_dist, distance ) ); } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ Fail: exc->GS.rp1 = exc->GS.rp0; if ( ( exc->opcode & 16 ) != 0 ) exc->GS.rp0 = point; exc->GS.rp2 = point; } /************************************************************************** * * ALIGNRP[]: ALIGN Relative Point * Opcode range: 0x3C * Stack: uint32 uint32... --> */ static void Ins_ALIGNRP( TT_ExecContext exc ) { FT_UShort point; FT_F26Dot6 distance; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->iup_called && ( exc->sph_tweak_flags & SPH_TWEAK_NO_ALIGNRP_AFTER_IUP ) ) { exc->error = FT_THROW( Invalid_Reference ); goto Fail; } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ if ( exc->top < exc->GS.loop || BOUNDS( exc->GS.rp0, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } while ( exc->GS.loop > 0 ) { exc->args--; point = (FT_UShort)exc->stack[exc->args]; if ( BOUNDS( point, exc->zp1.n_points ) ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Invalid_Reference ); return; } } else { distance = PROJECT( exc->zp1.cur + point, exc->zp0.cur + exc->GS.rp0 ); exc->func_move( exc, &exc->zp1, point, NEG_LONG( distance ) ); } exc->GS.loop--; } Fail: exc->GS.loop = 1; exc->new_top = exc->args; } /************************************************************************** * * ISECT[]: moves point to InterSECTion * Opcode range: 0x0F * Stack: 5 * uint32 --> */ static void Ins_ISECT( TT_ExecContext exc, FT_Long* args ) { FT_UShort point, a0, a1, b0, b1; FT_F26Dot6 discriminant, dotproduct; FT_F26Dot6 dx, dy, dax, day, dbx, dby; FT_F26Dot6 val; FT_Vector R; point = (FT_UShort)args[0]; a0 = (FT_UShort)args[1]; a1 = (FT_UShort)args[2]; b0 = (FT_UShort)args[3]; b1 = (FT_UShort)args[4]; if ( BOUNDS( b0, exc->zp0.n_points ) || BOUNDS( b1, exc->zp0.n_points ) || BOUNDS( a0, exc->zp1.n_points ) || BOUNDS( a1, exc->zp1.n_points ) || BOUNDS( point, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } /* Cramer's rule */ dbx = SUB_LONG( exc->zp0.cur[b1].x, exc->zp0.cur[b0].x ); dby = SUB_LONG( exc->zp0.cur[b1].y, exc->zp0.cur[b0].y ); dax = SUB_LONG( exc->zp1.cur[a1].x, exc->zp1.cur[a0].x ); day = SUB_LONG( exc->zp1.cur[a1].y, exc->zp1.cur[a0].y ); dx = SUB_LONG( exc->zp0.cur[b0].x, exc->zp1.cur[a0].x ); dy = SUB_LONG( exc->zp0.cur[b0].y, exc->zp1.cur[a0].y ); discriminant = ADD_LONG( FT_MulDiv( dax, NEG_LONG( dby ), 0x40 ), FT_MulDiv( day, dbx, 0x40 ) ); dotproduct = ADD_LONG( FT_MulDiv( dax, dbx, 0x40 ), FT_MulDiv( day, dby, 0x40 ) ); /* The discriminant above is actually a cross product of vectors */ /* da and db. Together with the dot product, they can be used as */ /* surrogates for sine and cosine of the angle between the vectors. */ /* Indeed, */ /* dotproduct = |da||db|cos(angle) */ /* discriminant = |da||db|sin(angle) . */ /* We use these equations to reject grazing intersections by */ /* thresholding abs(tan(angle)) at 1/19, corresponding to 3 degrees. */ if ( MUL_LONG( 19, FT_ABS( discriminant ) ) > FT_ABS( dotproduct ) ) { val = ADD_LONG( FT_MulDiv( dx, NEG_LONG( dby ), 0x40 ), FT_MulDiv( dy, dbx, 0x40 ) ); R.x = FT_MulDiv( val, dax, discriminant ); R.y = FT_MulDiv( val, day, discriminant ); /* XXX: Block in backward_compatibility and/or post-IUP? */ exc->zp2.cur[point].x = ADD_LONG( exc->zp1.cur[a0].x, R.x ); exc->zp2.cur[point].y = ADD_LONG( exc->zp1.cur[a0].y, R.y ); } else { /* else, take the middle of the middles of A and B */ /* XXX: Block in backward_compatibility and/or post-IUP? */ exc->zp2.cur[point].x = ADD_LONG( ADD_LONG( exc->zp1.cur[a0].x, exc->zp1.cur[a1].x ), ADD_LONG( exc->zp0.cur[b0].x, exc->zp0.cur[b1].x ) ) / 4; exc->zp2.cur[point].y = ADD_LONG( ADD_LONG( exc->zp1.cur[a0].y, exc->zp1.cur[a1].y ), ADD_LONG( exc->zp0.cur[b0].y, exc->zp0.cur[b1].y ) ) / 4; } exc->zp2.tags[point] |= FT_CURVE_TAG_TOUCH_BOTH; } /************************************************************************** * * ALIGNPTS[]: ALIGN PoinTS * Opcode range: 0x27 * Stack: uint32 uint32 --> */ static void Ins_ALIGNPTS( TT_ExecContext exc, FT_Long* args ) { FT_UShort p1, p2; FT_F26Dot6 distance; p1 = (FT_UShort)args[0]; p2 = (FT_UShort)args[1]; if ( BOUNDS( p1, exc->zp1.n_points ) || BOUNDS( p2, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } distance = PROJECT( exc->zp0.cur + p2, exc->zp1.cur + p1 ) / 2; exc->func_move( exc, &exc->zp1, p1, distance ); exc->func_move( exc, &exc->zp0, p2, NEG_LONG( distance ) ); } /************************************************************************** * * IP[]: Interpolate Point * Opcode range: 0x39 * Stack: uint32... --> */ /* SOMETIMES, DUMBER CODE IS BETTER CODE */ static void Ins_IP( TT_ExecContext exc ) { FT_F26Dot6 old_range, cur_range; FT_Vector* orus_base; FT_Vector* cur_base; FT_Int twilight; if ( exc->top < exc->GS.loop ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } /* * We need to deal in a special way with the twilight zone. * Otherwise, by definition, the value of exc->twilight.orus[n] is (0,0), * for every n. */ twilight = ( exc->GS.gep0 == 0 || exc->GS.gep1 == 0 || exc->GS.gep2 == 0 ); if ( BOUNDS( exc->GS.rp1, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); goto Fail; } if ( twilight ) orus_base = &exc->zp0.org[exc->GS.rp1]; else orus_base = &exc->zp0.orus[exc->GS.rp1]; cur_base = &exc->zp0.cur[exc->GS.rp1]; /* XXX: There are some glyphs in some braindead but popular */ /* fonts out there (e.g. [aeu]grave in monotype.ttf) */ /* calling IP[] with bad values of rp[12]. */ /* Do something sane when this odd thing happens. */ if ( BOUNDS( exc->GS.rp1, exc->zp0.n_points ) || BOUNDS( exc->GS.rp2, exc->zp1.n_points ) ) { old_range = 0; cur_range = 0; } else { if ( twilight ) old_range = DUALPROJ( &exc->zp1.org[exc->GS.rp2], orus_base ); else if ( exc->metrics.x_scale == exc->metrics.y_scale ) old_range = DUALPROJ( &exc->zp1.orus[exc->GS.rp2], orus_base ); else { FT_Vector vec; vec.x = FT_MulFix( SUB_LONG( exc->zp1.orus[exc->GS.rp2].x, orus_base->x ), exc->metrics.x_scale ); vec.y = FT_MulFix( SUB_LONG( exc->zp1.orus[exc->GS.rp2].y, orus_base->y ), exc->metrics.y_scale ); old_range = FAST_DUALPROJ( &vec ); } cur_range = PROJECT( &exc->zp1.cur[exc->GS.rp2], cur_base ); } for ( ; exc->GS.loop > 0; exc->GS.loop-- ) { FT_UInt point = (FT_UInt)exc->stack[--exc->args]; FT_F26Dot6 org_dist, cur_dist, new_dist; /* check point bounds */ if ( BOUNDS( point, exc->zp2.n_points ) ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Invalid_Reference ); return; } continue; } if ( twilight ) org_dist = DUALPROJ( &exc->zp2.org[point], orus_base ); else if ( exc->metrics.x_scale == exc->metrics.y_scale ) org_dist = DUALPROJ( &exc->zp2.orus[point], orus_base ); else { FT_Vector vec; vec.x = FT_MulFix( SUB_LONG( exc->zp2.orus[point].x, orus_base->x ), exc->metrics.x_scale ); vec.y = FT_MulFix( SUB_LONG( exc->zp2.orus[point].y, orus_base->y ), exc->metrics.y_scale ); org_dist = FAST_DUALPROJ( &vec ); } cur_dist = PROJECT( &exc->zp2.cur[point], cur_base ); if ( org_dist ) { if ( old_range ) new_dist = FT_MulDiv( org_dist, cur_range, old_range ); else { /* This is the same as what MS does for the invalid case: */ /* */ /* delta = (Original_Pt - Original_RP1) - */ /* (Current_Pt - Current_RP1) ; */ /* */ /* In FreeType speak: */ /* */ /* delta = org_dist - cur_dist . */ /* */ /* We move `point' by `new_dist - cur_dist' after leaving */ /* this block, thus we have */ /* */ /* new_dist - cur_dist = delta , */ /* new_dist - cur_dist = org_dist - cur_dist , */ /* new_dist = org_dist . */ new_dist = org_dist; } } else new_dist = 0; exc->func_move( exc, &exc->zp2, (FT_UShort)point, SUB_LONG( new_dist, cur_dist ) ); } Fail: exc->GS.loop = 1; exc->new_top = exc->args; } /************************************************************************** * * UTP[a]: UnTouch Point * Opcode range: 0x29 * Stack: uint32 --> */ static void Ins_UTP( TT_ExecContext exc, FT_Long* args ) { FT_UShort point; FT_Byte mask; point = (FT_UShort)args[0]; if ( BOUNDS( point, exc->zp0.n_points ) ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); return; } mask = 0xFF; if ( exc->GS.freeVector.x != 0 ) mask &= ~FT_CURVE_TAG_TOUCH_X; if ( exc->GS.freeVector.y != 0 ) mask &= ~FT_CURVE_TAG_TOUCH_Y; exc->zp0.tags[point] &= mask; } /* Local variables for Ins_IUP: */ typedef struct IUP_WorkerRec_ { FT_Vector* orgs; /* original and current coordinate */ FT_Vector* curs; /* arrays */ FT_Vector* orus; FT_UInt max_points; } IUP_WorkerRec, *IUP_Worker; static void _iup_worker_shift( IUP_Worker worker, FT_UInt p1, FT_UInt p2, FT_UInt p ) { FT_UInt i; FT_F26Dot6 dx; dx = SUB_LONG( worker->curs[p].x, worker->orgs[p].x ); if ( dx != 0 ) { for ( i = p1; i < p; i++ ) worker->curs[i].x = ADD_LONG( worker->curs[i].x, dx ); for ( i = p + 1; i <= p2; i++ ) worker->curs[i].x = ADD_LONG( worker->curs[i].x, dx ); } } static void _iup_worker_interpolate( IUP_Worker worker, FT_UInt p1, FT_UInt p2, FT_UInt ref1, FT_UInt ref2 ) { FT_UInt i; FT_F26Dot6 orus1, orus2, org1, org2, cur1, cur2, delta1, delta2; if ( p1 > p2 ) return; if ( BOUNDS( ref1, worker->max_points ) || BOUNDS( ref2, worker->max_points ) ) return; orus1 = worker->orus[ref1].x; orus2 = worker->orus[ref2].x; if ( orus1 > orus2 ) { FT_F26Dot6 tmp_o; FT_UInt tmp_r; tmp_o = orus1; orus1 = orus2; orus2 = tmp_o; tmp_r = ref1; ref1 = ref2; ref2 = tmp_r; } org1 = worker->orgs[ref1].x; org2 = worker->orgs[ref2].x; cur1 = worker->curs[ref1].x; cur2 = worker->curs[ref2].x; delta1 = SUB_LONG( cur1, org1 ); delta2 = SUB_LONG( cur2, org2 ); if ( cur1 == cur2 || orus1 == orus2 ) { /* trivial snap or shift of untouched points */ for ( i = p1; i <= p2; i++ ) { FT_F26Dot6 x = worker->orgs[i].x; if ( x <= org1 ) x = ADD_LONG( x, delta1 ); else if ( x >= org2 ) x = ADD_LONG( x, delta2 ); else x = cur1; worker->curs[i].x = x; } } else { FT_Fixed scale = 0; FT_Bool scale_valid = 0; /* interpolation */ for ( i = p1; i <= p2; i++ ) { FT_F26Dot6 x = worker->orgs[i].x; if ( x <= org1 ) x = ADD_LONG( x, delta1 ); else if ( x >= org2 ) x = ADD_LONG( x, delta2 ); else { if ( !scale_valid ) { scale_valid = 1; scale = FT_DivFix( SUB_LONG( cur2, cur1 ), SUB_LONG( orus2, orus1 ) ); } x = ADD_LONG( cur1, FT_MulFix( SUB_LONG( worker->orus[i].x, orus1 ), scale ) ); } worker->curs[i].x = x; } } } /************************************************************************** * * IUP[a]: Interpolate Untouched Points * Opcode range: 0x30-0x31 * Stack: --> */ static void Ins_IUP( TT_ExecContext exc ) { IUP_WorkerRec V; FT_Byte mask; FT_UInt first_point; /* first point of contour */ FT_UInt end_point; /* end point (last+1) of contour */ FT_UInt first_touched; /* first touched point in contour */ FT_UInt cur_touched; /* current touched point in contour */ FT_UInt point; /* current point */ FT_Short contour; /* current contour */ #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* See `ttinterp.h' for details on backward compatibility mode. */ /* Allow IUP until it has been called on both axes. Immediately */ /* return on subsequent ones. */ if ( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility ) { if ( exc->iupx_called && exc->iupy_called ) return; if ( exc->opcode & 1 ) exc->iupx_called = TRUE; else exc->iupy_called = TRUE; } #endif /* ignore empty outlines */ if ( exc->pts.n_contours == 0 ) return; if ( exc->opcode & 1 ) { mask = FT_CURVE_TAG_TOUCH_X; V.orgs = exc->pts.org; V.curs = exc->pts.cur; V.orus = exc->pts.orus; } else { mask = FT_CURVE_TAG_TOUCH_Y; V.orgs = (FT_Vector*)( (FT_Pos*)exc->pts.org + 1 ); V.curs = (FT_Vector*)( (FT_Pos*)exc->pts.cur + 1 ); V.orus = (FT_Vector*)( (FT_Pos*)exc->pts.orus + 1 ); } V.max_points = exc->pts.n_points; contour = 0; point = 0; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode ) { exc->iup_called = TRUE; if ( exc->sph_tweak_flags & SPH_TWEAK_SKIP_IUP ) return; } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ do { end_point = exc->pts.contours[contour] - exc->pts.first_point; first_point = point; if ( BOUNDS( end_point, exc->pts.n_points ) ) end_point = exc->pts.n_points - 1; while ( point <= end_point && ( exc->pts.tags[point] & mask ) == 0 ) point++; if ( point <= end_point ) { first_touched = point; cur_touched = point; point++; while ( point <= end_point ) { if ( ( exc->pts.tags[point] & mask ) != 0 ) { _iup_worker_interpolate( &V, cur_touched + 1, point - 1, cur_touched, point ); cur_touched = point; } point++; } if ( cur_touched == first_touched ) _iup_worker_shift( &V, first_point, end_point, cur_touched ); else { _iup_worker_interpolate( &V, (FT_UShort)( cur_touched + 1 ), end_point, cur_touched, first_touched ); if ( first_touched > 0 ) _iup_worker_interpolate( &V, first_point, first_touched - 1, cur_touched, first_touched ); } } contour++; } while ( contour < exc->pts.n_contours ); } /************************************************************************** * * DELTAPn[]: DELTA exceptions P1, P2, P3 * Opcode range: 0x5D,0x71,0x72 * Stack: uint32 (2 * uint32)... --> */ static void Ins_DELTAP( TT_ExecContext exc, FT_Long* args ) { FT_ULong nump, k; FT_UShort A; FT_ULong C, P; FT_Long B; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY FT_UShort B1, B2; if ( SUBPIXEL_HINTING_INFINALITY && exc->ignore_x_mode && exc->iup_called && ( exc->sph_tweak_flags & SPH_TWEAK_NO_DELTAP_AFTER_IUP ) ) goto Fail; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ P = (FT_ULong)exc->func_cur_ppem( exc ); nump = (FT_ULong)args[0]; /* some points theoretically may occur more than once, thus UShort isn't enough */ for ( k = 1; k <= nump; k++ ) { if ( exc->args < 2 ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Too_Few_Arguments ); exc->args = 0; goto Fail; } exc->args -= 2; A = (FT_UShort)exc->stack[exc->args + 1]; B = exc->stack[exc->args]; /* XXX: Because some popular fonts contain some invalid DeltaP */ /* instructions, we simply ignore them when the stacked */ /* point reference is off limit, rather than returning an */ /* error. As a delta instruction doesn't change a glyph */ /* in great ways, this shouldn't be a problem. */ if ( !BOUNDS( A, exc->zp0.n_points ) ) { C = ( (FT_ULong)B & 0xF0 ) >> 4; switch ( exc->opcode ) { case 0x5D: break; case 0x71: C += 16; break; case 0x72: C += 32; break; } C += exc->GS.delta_base; if ( P == C ) { B = ( (FT_ULong)B & 0xF ) - 8; if ( B >= 0 ) B++; B *= 1L << ( 6 - exc->GS.delta_shift ); #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY ) { /* * Allow delta move if * * - not using ignore_x_mode rendering, * - glyph is specifically set to allow it, or * - glyph is composite and freedom vector is not in subpixel * direction. */ if ( !exc->ignore_x_mode || ( exc->sph_tweak_flags & SPH_TWEAK_ALWAYS_DO_DELTAP ) || ( exc->is_composite && exc->GS.freeVector.y != 0 ) ) exc->func_move( exc, &exc->zp0, A, B ); /* Otherwise, apply subpixel hinting and compatibility mode */ /* rules, always skipping deltas in subpixel direction. */ else if ( exc->ignore_x_mode && exc->GS.freeVector.y != 0 ) { /* save the y value of the point now; compare after move */ B1 = (FT_UShort)exc->zp0.cur[A].y; /* Standard subpixel hinting: Allow y move for y-touched */ /* points. This messes up DejaVu ... */ if ( !exc->face->sph_compatibility_mode && ( exc->zp0.tags[A] & FT_CURVE_TAG_TOUCH_Y ) ) exc->func_move( exc, &exc->zp0, A, B ); /* compatibility mode */ else if ( exc->face->sph_compatibility_mode && !( exc->sph_tweak_flags & SPH_TWEAK_ALWAYS_SKIP_DELTAP ) ) { if ( exc->sph_tweak_flags & SPH_TWEAK_ROUND_NONPIXEL_Y_MOVES ) B = FT_PIX_ROUND( B1 + B ) - B1; /* Allow delta move if using sph_compatibility_mode, */ /* IUP has not been called, and point is touched on Y. */ if ( !exc->iup_called && ( exc->zp0.tags[A] & FT_CURVE_TAG_TOUCH_Y ) ) exc->func_move( exc, &exc->zp0, A, B ); } B2 = (FT_UShort)exc->zp0.cur[A].y; /* Reverse this move if it results in a disallowed move */ if ( exc->GS.freeVector.y != 0 && ( ( exc->face->sph_compatibility_mode && ( B1 & 63 ) == 0 && ( B2 & 63 ) != 0 ) || ( ( exc->sph_tweak_flags & SPH_TWEAK_SKIP_NONPIXEL_Y_MOVES_DELTAP ) && ( B1 & 63 ) != 0 && ( B2 & 63 ) != 0 ) ) ) exc->func_move( exc, &exc->zp0, A, NEG_LONG( B ) ); } } else #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ { #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* See `ttinterp.h' for details on backward compatibility */ /* mode. */ if ( SUBPIXEL_HINTING_MINIMAL && exc->backward_compatibility ) { if ( !( exc->iupx_called && exc->iupy_called ) && ( ( exc->is_composite && exc->GS.freeVector.y != 0 ) || ( exc->zp0.tags[A] & FT_CURVE_TAG_TOUCH_Y ) ) ) exc->func_move( exc, &exc->zp0, A, B ); } else #endif exc->func_move( exc, &exc->zp0, A, B ); } } } else if ( exc->pedantic_hinting ) exc->error = FT_THROW( Invalid_Reference ); } Fail: exc->new_top = exc->args; } /************************************************************************** * * DELTACn[]: DELTA exceptions C1, C2, C3 * Opcode range: 0x73,0x74,0x75 * Stack: uint32 (2 * uint32)... --> */ static void Ins_DELTAC( TT_ExecContext exc, FT_Long* args ) { FT_ULong nump, k; FT_ULong A, C, P; FT_Long B; P = (FT_ULong)exc->func_cur_ppem( exc ); nump = (FT_ULong)args[0]; for ( k = 1; k <= nump; k++ ) { if ( exc->args < 2 ) { if ( exc->pedantic_hinting ) exc->error = FT_THROW( Too_Few_Arguments ); exc->args = 0; goto Fail; } exc->args -= 2; A = (FT_ULong)exc->stack[exc->args + 1]; B = exc->stack[exc->args]; if ( BOUNDSL( A, exc->cvtSize ) ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Invalid_Reference ); return; } } else { C = ( (FT_ULong)B & 0xF0 ) >> 4; switch ( exc->opcode ) { case 0x73: break; case 0x74: C += 16; break; case 0x75: C += 32; break; } C += exc->GS.delta_base; if ( P == C ) { B = ( (FT_ULong)B & 0xF ) - 8; if ( B >= 0 ) B++; B *= 1L << ( 6 - exc->GS.delta_shift ); exc->func_move_cvt( exc, A, B ); } } } Fail: exc->new_top = exc->args; } /************************************************************************** * * MISC. INSTRUCTIONS * */ /************************************************************************** * * GETINFO[]: GET INFOrmation * Opcode range: 0x88 * Stack: uint32 --> uint32 * * XXX: UNDOCUMENTED: Selector bits higher than 9 are currently (May * 2015) not documented in the OpenType specification. * * Selector bit 11 is incorrectly described as bit 8, while the * real meaning of bit 8 (vertical LCD subpixels) stays * undocumented. The same mistake can be found in Greg Hitchcock's * whitepaper. */ static void Ins_GETINFO( TT_ExecContext exc, FT_Long* args ) { FT_Long K; TT_Driver driver = (TT_Driver)FT_FACE_DRIVER( exc->face ); K = 0; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY /********************************* * RASTERIZER VERSION * Selector Bit: 0 * Return Bit(s): 0-7 */ if ( SUBPIXEL_HINTING_INFINALITY && ( args[0] & 1 ) != 0 && exc->subpixel_hinting ) { if ( exc->ignore_x_mode ) { /* if in ClearType backward compatibility mode, */ /* we sometimes change the TrueType version dynamically */ K = exc->rasterizer_version; FT_TRACE6(( "Setting rasterizer version %d\n", exc->rasterizer_version )); } else K = TT_INTERPRETER_VERSION_38; } else #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ if ( ( args[0] & 1 ) != 0 ) K = driver->interpreter_version; /********************************* * GLYPH ROTATED * Selector Bit: 1 * Return Bit(s): 8 */ if ( ( args[0] & 2 ) != 0 && exc->tt_metrics.rotated ) K |= 1 << 8; /********************************* * GLYPH STRETCHED * Selector Bit: 2 * Return Bit(s): 9 */ if ( ( args[0] & 4 ) != 0 && exc->tt_metrics.stretched ) K |= 1 << 9; #ifdef TT_CONFIG_OPTION_GX_VAR_SUPPORT /********************************* * VARIATION GLYPH * Selector Bit: 3 * Return Bit(s): 10 * * XXX: UNDOCUMENTED! */ if ( (args[0] & 8 ) != 0 && exc->face->blend ) K |= 1 << 10; #endif /********************************* * BI-LEVEL HINTING AND * GRAYSCALE RENDERING * Selector Bit: 5 * Return Bit(s): 12 */ if ( ( args[0] & 32 ) != 0 && exc->grayscale ) K |= 1 << 12; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* Toggle the following flags only outside of monochrome mode. */ /* Otherwise, instructions may behave weirdly and rendering results */ /* may differ between v35 and v40 mode, e.g., in `Times New Roman */ /* Bold Italic'. */ if ( SUBPIXEL_HINTING_MINIMAL && exc->subpixel_hinting_lean ) { /********************************* * HINTING FOR SUBPIXEL * Selector Bit: 6 * Return Bit(s): 13 * * v40 does subpixel hinting by default. */ if ( ( args[0] & 64 ) != 0 ) K |= 1 << 13; /********************************* * VERTICAL LCD SUBPIXELS? * Selector Bit: 8 * Return Bit(s): 15 */ if ( ( args[0] & 256 ) != 0 && exc->vertical_lcd_lean ) K |= 1 << 15; /********************************* * SUBPIXEL POSITIONED? * Selector Bit: 10 * Return Bit(s): 17 * * XXX: FreeType supports it, dependent on what client does? */ if ( ( args[0] & 1024 ) != 0 ) K |= 1 << 17; /********************************* * SYMMETRICAL SMOOTHING * Selector Bit: 11 * Return Bit(s): 18 * * The only smoothing method FreeType supports unless someone sets * FT_LOAD_TARGET_MONO. */ if ( ( args[0] & 2048 ) != 0 && exc->subpixel_hinting_lean ) K |= 1 << 18; /********************************* * CLEARTYPE HINTING AND * GRAYSCALE RENDERING * Selector Bit: 12 * Return Bit(s): 19 * * Grayscale rendering is what FreeType does anyway unless someone * sets FT_LOAD_TARGET_MONO or FT_LOAD_TARGET_LCD(_V) */ if ( ( args[0] & 4096 ) != 0 && exc->grayscale_cleartype ) K |= 1 << 19; } #endif #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY && exc->rasterizer_version >= TT_INTERPRETER_VERSION_35 ) { if ( exc->rasterizer_version >= 37 ) { /********************************* * HINTING FOR SUBPIXEL * Selector Bit: 6 * Return Bit(s): 13 */ if ( ( args[0] & 64 ) != 0 && exc->subpixel_hinting ) K |= 1 << 13; /********************************* * COMPATIBLE WIDTHS ENABLED * Selector Bit: 7 * Return Bit(s): 14 * * Functionality still needs to be added */ if ( ( args[0] & 128 ) != 0 && exc->compatible_widths ) K |= 1 << 14; /********************************* * VERTICAL LCD SUBPIXELS? * Selector Bit: 8 * Return Bit(s): 15 * * Functionality still needs to be added */ if ( ( args[0] & 256 ) != 0 && exc->vertical_lcd ) K |= 1 << 15; /********************************* * HINTING FOR BGR? * Selector Bit: 9 * Return Bit(s): 16 * * Functionality still needs to be added */ if ( ( args[0] & 512 ) != 0 && exc->bgr ) K |= 1 << 16; if ( exc->rasterizer_version >= 38 ) { /********************************* * SUBPIXEL POSITIONED? * Selector Bit: 10 * Return Bit(s): 17 * * Functionality still needs to be added */ if ( ( args[0] & 1024 ) != 0 && exc->subpixel_positioned ) K |= 1 << 17; /********************************* * SYMMETRICAL SMOOTHING * Selector Bit: 11 * Return Bit(s): 18 * * Functionality still needs to be added */ if ( ( args[0] & 2048 ) != 0 && exc->symmetrical_smoothing ) K |= 1 << 18; /********************************* * GRAY CLEARTYPE * Selector Bit: 12 * Return Bit(s): 19 * * Functionality still needs to be added */ if ( ( args[0] & 4096 ) != 0 && exc->gray_cleartype ) K |= 1 << 19; } } } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ args[0] = K; } #ifdef TT_CONFIG_OPTION_GX_VAR_SUPPORT /************************************************************************** * * GETVARIATION[]: get normalized variation (blend) coordinates * Opcode range: 0x91 * Stack: --> f2.14... * * XXX: UNDOCUMENTED! There is no official documentation from Apple for * this bytecode instruction. Active only if a font has GX * variation axes. */ static void Ins_GETVARIATION( TT_ExecContext exc, FT_Long* args ) { FT_UInt num_axes = exc->face->blend->num_axis; FT_Fixed* coords = exc->face->blend->normalizedcoords; FT_UInt i; if ( BOUNDS( num_axes, exc->stackSize + 1 - exc->top ) ) { exc->error = FT_THROW( Stack_Overflow ); return; } if ( coords ) { for ( i = 0; i < num_axes; i++ ) args[i] = coords[i] >> 2; /* convert 16.16 to 2.14 format */ } else { for ( i = 0; i < num_axes; i++ ) args[i] = 0; } } /************************************************************************** * * GETDATA[]: no idea what this is good for * Opcode range: 0x92 * Stack: --> 17 * * XXX: UNDOCUMENTED! There is no documentation from Apple for this * very weird bytecode instruction. */ static void Ins_GETDATA( FT_Long* args ) { args[0] = 17; } #endif /* TT_CONFIG_OPTION_GX_VAR_SUPPORT */ static void Ins_UNKNOWN( TT_ExecContext exc ) { TT_DefRecord* def = exc->IDefs; TT_DefRecord* limit = def + exc->numIDefs; for ( ; def < limit; def++ ) { if ( (FT_Byte)def->opc == exc->opcode && def->active ) { TT_CallRec* call; if ( exc->callTop >= exc->callSize ) { exc->error = FT_THROW( Stack_Overflow ); return; } call = exc->callStack + exc->callTop++; call->Caller_Range = exc->curRange; call->Caller_IP = exc->IP + 1; call->Cur_Count = 1; call->Def = def; Ins_Goto_CodeRange( exc, def->range, def->start ); exc->step_ins = FALSE; return; } } exc->error = FT_THROW( Invalid_Opcode ); } /************************************************************************** * * RUN * * This function executes a run of opcodes. It will exit in the * following cases: * * - Errors (in which case it returns FALSE). * * - Reaching the end of the main code range (returns TRUE). * Reaching the end of a code range within a function call is an * error. * * - After executing one single opcode, if the flag `Instruction_Trap' * is set to TRUE (returns TRUE). * * On exit with TRUE, test IP < CodeSize to know whether it comes from * an instruction trap or a normal termination. * * * Note: The documented DEBUG opcode pops a value from the stack. This * behaviour is unsupported; here a DEBUG opcode is always an * error. * * * THIS IS THE INTERPRETER'S MAIN LOOP. * */ /* documentation is in ttinterp.h */ FT_EXPORT_DEF( FT_Error ) TT_RunIns( TT_ExecContext exc ) { FT_ULong ins_counter = 0; /* executed instructions counter */ FT_ULong num_twilight_points; FT_UShort i; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY FT_Byte opcode_pattern[1][2] = { /* #8 TypeMan Talk Align */ { 0x06, /* SPVTL */ 0x7D, /* RDTG */ }, }; FT_UShort opcode_patterns = 1; FT_UShort opcode_pointer[1] = { 0 }; FT_UShort opcode_size[1] = { 1 }; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY exc->iup_called = FALSE; #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ #ifdef TT_SUPPORT_SUBPIXEL_HINTING_MINIMAL /* * Toggle backward compatibility according to what font wants, except * when * * 1) we have a `tricky' font that heavily relies on the interpreter to * render glyphs correctly, for example DFKai-SB, or * 2) FT_RENDER_MODE_MONO (i.e, monochome rendering) is requested. * * In those cases, backward compatibility needs to be turned off to get * correct rendering. The rendering is then completely up to the * font's programming. * */ if ( SUBPIXEL_HINTING_MINIMAL && exc->subpixel_hinting_lean && !FT_IS_TRICKY( &exc->face->root ) ) exc->backward_compatibility = !( exc->GS.instruct_control & 4 ); else exc->backward_compatibility = FALSE; exc->iupx_called = FALSE; exc->iupy_called = FALSE; #endif /* We restrict the number of twilight points to a reasonable, */ /* heuristic value to avoid slow execution of malformed bytecode. */ num_twilight_points = FT_MAX( 30, 2 * ( exc->pts.n_points + exc->cvtSize ) ); if ( exc->twilight.n_points > num_twilight_points ) { if ( num_twilight_points > 0xFFFFU ) num_twilight_points = 0xFFFFU; FT_TRACE5(( "TT_RunIns: Resetting number of twilight points\n" " from %d to the more reasonable value %d\n", exc->twilight.n_points, num_twilight_points )); exc->twilight.n_points = (FT_UShort)num_twilight_points; } /* Set up loop detectors. We restrict the number of LOOPCALL loops */ /* and the number of JMPR, JROT, and JROF calls with a negative */ /* argument to values that depend on various parameters like the */ /* size of the CVT table or the number of points in the current */ /* glyph (if applicable). */ /* */ /* The idea is that in real-world bytecode you either iterate over */ /* all CVT entries (in the `prep' table), or over all points (or */ /* contours, in the `glyf' table) of a glyph, and such iterations */ /* don't happen very often. */ exc->loopcall_counter = 0; exc->neg_jump_counter = 0; /* The maximum values are heuristic. */ if ( exc->pts.n_points ) exc->loopcall_counter_max = FT_MAX( 50, 10 * exc->pts.n_points ) + FT_MAX( 50, exc->cvtSize / 10 ); else exc->loopcall_counter_max = 300 + 8 * exc->cvtSize; /* as a protection against an unreasonable number of CVT entries */ /* we assume at most 100 control values per glyph for the counter */ if ( exc->loopcall_counter_max > 100 * (FT_ULong)exc->face->root.num_glyphs ) exc->loopcall_counter_max = 100 * (FT_ULong)exc->face->root.num_glyphs; FT_TRACE5(( "TT_RunIns: Limiting total number of loops in LOOPCALL" " to %d\n", exc->loopcall_counter_max )); exc->neg_jump_counter_max = exc->loopcall_counter_max; FT_TRACE5(( "TT_RunIns: Limiting total number of backward jumps" " to %d\n", exc->neg_jump_counter_max )); /* set PPEM and CVT functions */ exc->tt_metrics.ratio = 0; if ( exc->metrics.x_ppem != exc->metrics.y_ppem ) { /* non-square pixels, use the stretched routines */ exc->func_cur_ppem = Current_Ppem_Stretched; exc->func_read_cvt = Read_CVT_Stretched; exc->func_write_cvt = Write_CVT_Stretched; exc->func_move_cvt = Move_CVT_Stretched; } else { /* square pixels, use normal routines */ exc->func_cur_ppem = Current_Ppem; exc->func_read_cvt = Read_CVT; exc->func_write_cvt = Write_CVT; exc->func_move_cvt = Move_CVT; } Compute_Funcs( exc ); Compute_Round( exc, (FT_Byte)exc->GS.round_state ); do { exc->opcode = exc->code[exc->IP]; #ifdef FT_DEBUG_LEVEL_TRACE { FT_Long cnt = FT_MIN( 8, exc->top ); FT_Long n; /* if tracing level is 7, show current code position */ /* and the first few stack elements also */ FT_TRACE6(( " " )); FT_TRACE7(( "%06d ", exc->IP )); FT_TRACE6(( "%s", opcode_name[exc->opcode] + 2 )); FT_TRACE7(( "%*s", *opcode_name[exc->opcode] == 'A' ? 2 : 12 - ( *opcode_name[exc->opcode] - '0' ), "#" )); for ( n = 1; n <= cnt; n++ ) FT_TRACE7(( " %d", exc->stack[exc->top - n] )); FT_TRACE6(( "\n" )); } #endif /* FT_DEBUG_LEVEL_TRACE */ if ( ( exc->length = opcode_length[exc->opcode] ) < 0 ) { if ( exc->IP + 1 >= exc->codeSize ) goto LErrorCodeOverflow_; exc->length = 2 - exc->length * exc->code[exc->IP + 1]; } if ( exc->IP + exc->length > exc->codeSize ) goto LErrorCodeOverflow_; /* First, let's check for empty stack and overflow */ exc->args = exc->top - ( Pop_Push_Count[exc->opcode] >> 4 ); /* `args' is the top of the stack once arguments have been popped. */ /* One can also interpret it as the index of the last argument. */ if ( exc->args < 0 ) { if ( exc->pedantic_hinting ) { exc->error = FT_THROW( Too_Few_Arguments ); goto LErrorLabel_; } /* push zeroes onto the stack */ for ( i = 0; i < Pop_Push_Count[exc->opcode] >> 4; i++ ) exc->stack[i] = 0; exc->args = 0; } #ifdef TT_CONFIG_OPTION_GX_VAR_SUPPORT if ( exc->opcode == 0x91 ) { /* this is very special: GETVARIATION returns */ /* a variable number of arguments */ /* it is the job of the application to `activate' GX handling, */ /* this is, calling any of the GX API functions on the current */ /* font to select a variation instance */ if ( exc->face->blend ) exc->new_top = exc->args + exc->face->blend->num_axis; } else #endif exc->new_top = exc->args + ( Pop_Push_Count[exc->opcode] & 15 ); /* `new_top' is the new top of the stack, after the instruction's */ /* execution. `top' will be set to `new_top' after the `switch' */ /* statement. */ if ( exc->new_top > exc->stackSize ) { exc->error = FT_THROW( Stack_Overflow ); goto LErrorLabel_; } exc->step_ins = TRUE; exc->error = FT_Err_Ok; #ifdef TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY if ( SUBPIXEL_HINTING_INFINALITY ) { for ( i = 0; i < opcode_patterns; i++ ) { if ( opcode_pointer[i] < opcode_size[i] && exc->opcode == opcode_pattern[i][opcode_pointer[i]] ) { opcode_pointer[i] += 1; if ( opcode_pointer[i] == opcode_size[i] ) { FT_TRACE6(( "sph: opcode ptrn: %d, %s %s\n", i, exc->face->root.family_name, exc->face->root.style_name )); switch ( i ) { case 0: break; } opcode_pointer[i] = 0; } } else opcode_pointer[i] = 0; } } #endif /* TT_SUPPORT_SUBPIXEL_HINTING_INFINALITY */ { FT_Long* args = exc->stack + exc->args; FT_Byte opcode = exc->opcode; switch ( opcode ) { case 0x00: /* SVTCA y */ case 0x01: /* SVTCA x */ case 0x02: /* SPvTCA y */ case 0x03: /* SPvTCA x */ case 0x04: /* SFvTCA y */ case 0x05: /* SFvTCA x */ Ins_SxyTCA( exc ); break; case 0x06: /* SPvTL // */ case 0x07: /* SPvTL + */ Ins_SPVTL( exc, args ); break; case 0x08: /* SFvTL // */ case 0x09: /* SFvTL + */ Ins_SFVTL( exc, args ); break; case 0x0A: /* SPvFS */ Ins_SPVFS( exc, args ); break; case 0x0B: /* SFvFS */ Ins_SFVFS( exc, args ); break; case 0x0C: /* GPv */ Ins_GPV( exc, args ); break; case 0x0D: /* GFv */ Ins_GFV( exc, args ); break; case 0x0E: /* SFvTPv */ Ins_SFVTPV( exc ); break; case 0x0F: /* ISECT */ Ins_ISECT( exc, args ); break; case 0x10: /* SRP0 */ Ins_SRP0( exc, args ); break; case 0x11: /* SRP1 */ Ins_SRP1( exc, args ); break; case 0x12: /* SRP2 */ Ins_SRP2( exc, args ); break; case 0x13: /* SZP0 */ Ins_SZP0( exc, args ); break; case 0x14: /* SZP1 */ Ins_SZP1( exc, args ); break; case 0x15: /* SZP2 */ Ins_SZP2( exc, args ); break; case 0x16: /* SZPS */ Ins_SZPS( exc, args ); break; case 0x17: /* SLOOP */ Ins_SLOOP( exc, args ); break; case 0x18: /* RTG */ Ins_RTG( exc ); break; case 0x19: /* RTHG */ Ins_RTHG( exc ); break; case 0x1A: /* SMD */ Ins_SMD( exc, args ); break; case 0x1B: /* ELSE */ Ins_ELSE( exc ); break; case 0x1C: /* JMPR */ Ins_JMPR( exc, args ); break; case 0x1D: /* SCVTCI */ Ins_SCVTCI( exc, args ); break; case 0x1E: /* SSWCI */ Ins_SSWCI( exc, args ); break; case 0x1F: /* SSW */ Ins_SSW( exc, args ); break; case 0x20: /* DUP */ Ins_DUP( args ); break; case 0x21: /* POP */ Ins_POP(); break; case 0x22: /* CLEAR */ Ins_CLEAR( exc ); break; case 0x23: /* SWAP */ Ins_SWAP( args ); break; case 0x24: /* DEPTH */ Ins_DEPTH( exc, args ); break; case 0x25: /* CINDEX */ Ins_CINDEX( exc, args ); break; case 0x26: /* MINDEX */ Ins_MINDEX( exc, args ); break; case 0x27: /* ALIGNPTS */ Ins_ALIGNPTS( exc, args ); break; case 0x28: /* RAW */ Ins_UNKNOWN( exc ); break; case 0x29: /* UTP */ Ins_UTP( exc, args ); break; case 0x2A: /* LOOPCALL */ Ins_LOOPCALL( exc, args ); break; case 0x2B: /* CALL */ Ins_CALL( exc, args ); break; case 0x2C: /* FDEF */ Ins_FDEF( exc, args ); break; case 0x2D: /* ENDF */ Ins_ENDF( exc ); break; case 0x2E: /* MDAP */ case 0x2F: /* MDAP */ Ins_MDAP( exc, args ); break; case 0x30: /* IUP */ case 0x31: /* IUP */ Ins_IUP( exc ); break; case 0x32: /* SHP */ case 0x33: /* SHP */ Ins_SHP( exc ); break; case 0x34: /* SHC */ case 0x35: /* SHC */ Ins_SHC( exc, args ); break; case 0x36: /* SHZ */ case 0x37: /* SHZ */ Ins_SHZ( exc, args ); break; case 0x38: /* SHPIX */ Ins_SHPIX( exc, args ); break; case 0x39: /* IP */ Ins_IP( exc ); break; case 0x3A: /* MSIRP */ case 0x3B: /* MSIRP */ Ins_MSIRP( exc, args ); break; case 0x3C: /* AlignRP */ Ins_ALIGNRP( exc ); break; case 0x3D: /* RTDG */ Ins_RTDG( exc ); break; case 0x3E: /* MIAP */ case 0x3F: /* MIAP */ Ins_MIAP( exc, args ); break; case 0x40: /* NPUSHB */ Ins_NPUSHB( exc, args ); break; case 0x41: /* NPUSHW */ Ins_NPUSHW( exc, args ); break; case 0x42: /* WS */ Ins_WS( exc, args ); break; case 0x43: /* RS */ Ins_RS( exc, args ); break; case 0x44: /* WCVTP */ Ins_WCVTP( exc, args ); break; case 0x45: /* RCVT */ Ins_RCVT( exc, args ); break; case 0x46: /* GC */ case 0x47: /* GC */ Ins_GC( exc, args ); break; case 0x48: /* SCFS */ Ins_SCFS( exc, args ); break; case 0x49: /* MD */ case 0x4A: /* MD */ Ins_MD( exc, args ); break; case 0x4B: /* MPPEM */ Ins_MPPEM( exc, args ); break; case 0x4C: /* MPS */ Ins_MPS( exc, args ); break; case 0x4D: /* FLIPON */ Ins_FLIPON( exc ); break; case 0x4E: /* FLIPOFF */ Ins_FLIPOFF( exc ); break; case 0x4F: /* DEBUG */ Ins_DEBUG( exc ); break; case 0x50: /* LT */ Ins_LT( args ); break; case 0x51: /* LTEQ */ Ins_LTEQ( args ); break; case 0x52: /* GT */ Ins_GT( args ); break; case 0x53: /* GTEQ */ Ins_GTEQ( args ); break; case 0x54: /* EQ */ Ins_EQ( args ); break; case 0x55: /* NEQ */ Ins_NEQ( args ); break; case 0x56: /* ODD */ Ins_ODD( exc, args ); break; case 0x57: /* EVEN */ Ins_EVEN( exc, args ); break; case 0x58: /* IF */ Ins_IF( exc, args ); break; case 0x59: /* EIF */ Ins_EIF(); break; case 0x5A: /* AND */ Ins_AND( args ); break; case 0x5B: /* OR */ Ins_OR( args ); break; case 0x5C: /* NOT */ Ins_NOT( args ); break; case 0x5D: /* DELTAP1 */ Ins_DELTAP( exc, args ); break; case 0x5E: /* SDB */ Ins_SDB( exc, args ); break; case 0x5F: /* SDS */ Ins_SDS( exc, args ); break; case 0x60: /* ADD */ Ins_ADD( args ); break; case 0x61: /* SUB */ Ins_SUB( args ); break; case 0x62: /* DIV */ Ins_DIV( exc, args ); break; case 0x63: /* MUL */ Ins_MUL( args ); break; case 0x64: /* ABS */ Ins_ABS( args ); break; case 0x65: /* NEG */ Ins_NEG( args ); break; case 0x66: /* FLOOR */ Ins_FLOOR( args ); break; case 0x67: /* CEILING */ Ins_CEILING( args ); break; case 0x68: /* ROUND */ case 0x69: /* ROUND */ case 0x6A: /* ROUND */ case 0x6B: /* ROUND */ Ins_ROUND( exc, args ); break; case 0x6C: /* NROUND */ case 0x6D: /* NROUND */ case 0x6E: /* NRRUND */ case 0x6F: /* NROUND */ Ins_NROUND( exc, args ); break; case 0x70: /* WCVTF */ Ins_WCVTF( exc, args ); break; case 0x71: /* DELTAP2 */ case 0x72: /* DELTAP3 */ Ins_DELTAP( exc, args ); break; case 0x73: /* DELTAC0 */ case 0x74: /* DELTAC1 */ case 0x75: /* DELTAC2 */ Ins_DELTAC( exc, args ); break; case 0x76: /* SROUND */ Ins_SROUND( exc, args ); break; case 0x77: /* S45Round */ Ins_S45ROUND( exc, args ); break; case 0x78: /* JROT */ Ins_JROT( exc, args ); break; case 0x79: /* JROF */ Ins_JROF( exc, args ); break; case 0x7A: /* ROFF */ Ins_ROFF( exc ); break; case 0x7B: /* ???? */ Ins_UNKNOWN( exc ); break; case 0x7C: /* RUTG */ Ins_RUTG( exc ); break; case 0x7D: /* RDTG */ Ins_RDTG( exc ); break; case 0x7E: /* SANGW */ Ins_SANGW(); break; case 0x7F: /* AA */ Ins_AA(); break; case 0x80: /* FLIPPT */ Ins_FLIPPT( exc ); break; case 0x81: /* FLIPRGON */ Ins_FLIPRGON( exc, args ); break; case 0x82: /* FLIPRGOFF */ Ins_FLIPRGOFF( exc, args ); break; case 0x83: /* UNKNOWN */ case 0x84: /* UNKNOWN */ Ins_UNKNOWN( exc ); break; case 0x85: /* SCANCTRL */ Ins_SCANCTRL( exc, args ); break; case 0x86: /* SDPvTL */ case 0x87: /* SDPvTL */ Ins_SDPVTL( exc, args ); break; case 0x88: /* GETINFO */ Ins_GETINFO( exc, args ); break; case 0x89: /* IDEF */ Ins_IDEF( exc, args ); break; case 0x8A: /* ROLL */ Ins_ROLL( args ); break; case 0x8B: /* MAX */ Ins_MAX( args ); break; case 0x8C: /* MIN */ Ins_MIN( args ); break; case 0x8D: /* SCANTYPE */ Ins_SCANTYPE( exc, args ); break; case 0x8E: /* INSTCTRL */ Ins_INSTCTRL( exc, args ); break; case 0x8F: /* ADJUST */ case 0x90: /* ADJUST */ Ins_UNKNOWN( exc ); break; #ifdef TT_CONFIG_OPTION_GX_VAR_SUPPORT case 0x91: /* it is the job of the application to `activate' GX handling, */ /* this is, calling any of the GX API functions on the current */ /* font to select a variation instance */ if ( exc->face->blend ) Ins_GETVARIATION( exc, args ); else Ins_UNKNOWN( exc ); break; case 0x92: /* there is at least one MS font (LaoUI.ttf version 5.01) that */ /* uses IDEFs for 0x91 and 0x92; for this reason we activate */ /* GETDATA for GX fonts only, similar to GETVARIATION */ if ( exc->face->blend ) Ins_GETDATA( args ); else Ins_UNKNOWN( exc ); break; #endif default: if ( opcode >= 0xE0 ) Ins_MIRP( exc, args ); else if ( opcode >= 0xC0 ) Ins_MDRP( exc, args ); else if ( opcode >= 0xB8 ) Ins_PUSHW( exc, args ); else if ( opcode >= 0xB0 ) Ins_PUSHB( exc, args ); else Ins_UNKNOWN( exc ); } } if ( exc->error ) { switch ( exc->error ) { /* looking for redefined instructions */ case FT_ERR( Invalid_Opcode ): { TT_DefRecord* def = exc->IDefs; TT_DefRecord* limit = def + exc->numIDefs; for ( ; def < limit; def++ ) { if ( def->active && exc->opcode == (FT_Byte)def->opc ) { TT_CallRec* callrec; if ( exc->callTop >= exc->callSize ) { exc->error = FT_THROW( Invalid_Reference ); goto LErrorLabel_; } callrec = &exc->callStack[exc->callTop]; callrec->Caller_Range = exc->curRange; callrec->Caller_IP = exc->IP + 1; callrec->Cur_Count = 1; callrec->Def = def; if ( Ins_Goto_CodeRange( exc, def->range, def->start ) == FAILURE ) goto LErrorLabel_; goto LSuiteLabel_; } } } exc->error = FT_THROW( Invalid_Opcode ); goto LErrorLabel_; #if 0 break; /* Unreachable code warning suppression. */ /* Leave to remind in case a later change the editor */ /* to consider break; */ #endif default: goto LErrorLabel_; #if 0 break; #endif } } exc->top = exc->new_top; if ( exc->step_ins ) exc->IP += exc->length; /* increment instruction counter and check if we didn't */ /* run this program for too long (e.g. infinite loops). */ if ( ++ins_counter > TT_CONFIG_OPTION_MAX_RUNNABLE_OPCODES ) return FT_THROW( Execution_Too_Long ); LSuiteLabel_: if ( exc->IP >= exc->codeSize ) { if ( exc->callTop > 0 ) { exc->error = FT_THROW( Code_Overflow ); goto LErrorLabel_; } else goto LNo_Error_; } } while ( !exc->instruction_trap ); LNo_Error_: FT_TRACE4(( " %d instruction%s executed\n", ins_counter, ins_counter == 1 ? "" : "s" )); return FT_Err_Ok; LErrorCodeOverflow_: exc->error = FT_THROW( Code_Overflow ); LErrorLabel_: if ( exc->error && !exc->instruction_trap ) FT_TRACE1(( " The interpreter returned error 0x%x\n", exc->error )); return exc->error; } #else /* !TT_USE_BYTECODE_INTERPRETER */ /* ANSI C doesn't like empty source files */ typedef int _tt_interp_dummy; #endif /* !TT_USE_BYTECODE_INTERPRETER */ /* END */