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Comment:merge trunk
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SHA3-256: d03f410e2ae15593b887122f16149f4311fe6ad504bcb3ddb63d51cb56779543
User & Date: dgp 2019-06-12 19:04:04
Context
2019-06-17
18:29
merge trunk check-in: fa4cdb8590 user: dgp tags: dgp-properbytearray
2019-06-12
19:04
merge trunk check-in: d03f410e2a user: dgp tags: dgp-properbytearray
15:42
Merge 8.7 check-in: c5ff3f41bd user: jan.nijtmans tags: trunk
2019-06-09
21:21
Merge trunk check-in: 86b6e6c0a9 user: jan.nijtmans tags: dgp-properbytearray
Changes
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Changes to doc/expr.n.

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\fBTcl\fR.
.PP
Below are some examples of simple expressions where the value of \fBa\fR is 3
and the value of \fBb\fR is 6.  The command on the left side of each line
produces the value on the right side.
.PP
.CS
.ta 6c
\fBexpr\fR 3.1 + $a	\fI6.1\fR
\fBexpr\fR 2 + "$a.$b"	\fI5.6\fR
\fBexpr\fR 4*[llength "6 2"]	\fI8\fR
\fBexpr\fR {{word one} < "word $a"}	\fI0\fR
.CE
.SS OPERATORS
.PP
................................................................................
\fB|\fR
.
Bit-wise OR.  Valid for integer operands.
.TP 20
\fB&&\fR
.
Logical AND.  If both operands are true, the result is 1, or 0 otherwise.





.TP 20
\fB||\fR
.
Logical OR.  If both operands are false, the result is 0, or 1 otherwise.


.TP 20
\fIx\fB?\fIy\fB:\fIz\fR

.
If-then-else, as in C.  If \fIx\fR is false , the result is the value of
\fIy\fR.  Otherwise the result is the value of \fIz\fR.

.PP
The exponentiation operator promotes types in the same way that the multiply
and divide operators do, and the result is is the same as the result of
\fBpow\fR.
Exponentiation groups right-to-left within a precedence level. Other binary
operators group left-to-right.  For example, the value of

.PP
.CS
\fBexpr\fR {4*2 < 7}
.CE
.PP
is 0, while the value of
.PP
................................................................................
substitutions on, enclosing an expression in braces or otherwise quoting it
so that it's a static value allows the Tcl compiler to generate bytecode for
the expression, resulting in better speed and smaller storage requirements.
This also avoids issues that can arise if Tcl is allowed to perform
substitution on the value before \fBexpr\fR is called.
.PP
In the following example, the value of the expression is 11 because the Tcl parser first
substitutes \fB$b\fR and \fBexpr\fR then substitutes \fB$a\fR.  Enclosing the



expression in braces would result in a syntax error.


.CS
set a 3
set b {$a + 2}
\fBexpr\fR $b*4
.CE
.PP

When an expression is generated at runtime, like the one above is, the bytcode
compiler must ensure that new code is generated each time the expression
is evaluated.  This is the most costly kind of expression from a performance
perspective.  In such cases, consider directly using the commands described in
the \fBmathfunc\fR(n) or \fBmathop\fR(n) documentation instead of \fBexpr\fR.

Most expressions are not formed at runtime, but are literal strings or contain
substitutions that don't introduce other substitutions.  To allow the bytecode
compiler to work with an expression as a string literal at compilation time,
ensure that it contains no substitutions or that it is enclosed in braces or
otherwise quoted to prevent Tcl from performing substitutions, allowing
\fBexpr\fR to perform them instead.




















.SH EXAMPLES
.PP
A numeric comparison whose result is 1:

.CS
\fBexpr\fR {"0x03" > "2"}
.CE
.PP
A string comparison whose result is 1:

.CS
\fBexpr\fR {"0y" > "0x12"}
.CE
.PP
Define a procedure that computes an
.QW interesting
mathematical function:






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\fBTcl\fR.
.PP
Below are some examples of simple expressions where the value of \fBa\fR is 3
and the value of \fBb\fR is 6.  The command on the left side of each line
produces the value on the right side.
.PP
.CS
.ta 9c
\fBexpr\fR 3.1 + $a	\fI6.1\fR
\fBexpr\fR 2 + "$a.$b"	\fI5.6\fR
\fBexpr\fR 4*[llength "6 2"]	\fI8\fR
\fBexpr\fR {{word one} < "word $a"}	\fI0\fR
.CE
.SS OPERATORS
.PP
................................................................................
\fB|\fR
.
Bit-wise OR.  Valid for integer operands.
.TP 20
\fB&&\fR
.
Logical AND.  If both operands are true, the result is 1, or 0 otherwise.

This operator evaluates lazily; it only evaluates its second operand if it
must in order to determine its result.
This operator evaluates lazily; it only evaluates its second operand if it
must in order to determine its result.
.TP 20
\fB||\fR
.
Logical OR.  If both operands are false, the result is 0, or 1 otherwise.
This operator evaluates lazily; it only evaluates its second operand if it
must in order to determine its result.
.TP 20

\fIx \fB?\fI y \fB:\fI z\fR
.
If-then-else, as in C.  If \fIx\fR is false , the result is the value of
\fIy\fR.  Otherwise the result is the value of \fIz\fR.
This operator evaluates lazily; it evaluates only one of \fIy\fR or \fIz\fR.
.PP
The exponentiation operator promotes types in the same way that the multiply
and divide operators do, and the result is is the same as the result of
\fBpow\fR.
Exponentiation groups right-to-left within a precedence level. Other binary
operators group left-to-right.  For example, the value of
.PP
.PP
.CS
\fBexpr\fR {4*2 < 7}
.CE
.PP
is 0, while the value of
.PP
................................................................................
substitutions on, enclosing an expression in braces or otherwise quoting it
so that it's a static value allows the Tcl compiler to generate bytecode for
the expression, resulting in better speed and smaller storage requirements.
This also avoids issues that can arise if Tcl is allowed to perform
substitution on the value before \fBexpr\fR is called.
.PP
In the following example, the value of the expression is 11 because the Tcl parser first
substitutes \fB$b\fR and \fBexpr\fR then substitutes \fB$a\fR as part
of evaluating the expression
.QW "$a + 2*4" .
Enclosing the
expression in braces would result in a syntax error as \fB$b\fR does
not evaluate to a numeric value.
.PP
.CS
set a 3
set b {$a + 2}
\fBexpr\fR $b*4
.CE
.PP

When an expression is generated at runtime, like the one above is, the bytecode
compiler must ensure that new code is generated each time the expression
is evaluated.  This is the most costly kind of expression from a performance
perspective.  In such cases, consider directly using the commands described in
the \fBmathfunc\fR(n) or \fBmathop\fR(n) documentation instead of \fBexpr\fR.
.PP
Most expressions are not formed at runtime, but are literal strings or contain
substitutions that don't introduce other substitutions.  To allow the bytecode
compiler to work with an expression as a string literal at compilation time,
ensure that it contains no substitutions or that it is enclosed in braces or
otherwise quoted to prevent Tcl from performing substitutions, allowing
\fBexpr\fR to perform them instead.
.PP
If it is necessary to include a non-constant expression string within the
wider context of an otherwise-constant expression, the most efficient
technique is to put the varying part inside a recursive \fBexpr\fR, as this at
least allows for the compilation of the outer part, though it does mean that
the varying part must itself be evaluated as a separate expression. Thus, in
this example the result is 20 and the outer expression benefits from fully
cached bytecode compilation.
.PP
.CS
set a 3
set b {$a + 2}
\fBexpr\fR {[\fBexpr\fR $b] * 4}
.CE
.PP
In general, you should enclose your expression in braces wherever possible,
and where not possible, the argument to \fBexpr\fR should be an expression
defined elsewhere as simply as possible. It is usually more efficient and
safer to use other techniques (e.g., the commands in the \fBtcl::mathop\fR
namespace) than it is to do complex expression generation.
.SH EXAMPLES
.PP
A numeric comparison whose result is 1:
.PP
.CS
\fBexpr\fR {"0x03" > "2"}
.CE
.PP
A string comparison whose result is 1:
.PP
.CS
\fBexpr\fR {"0y" > "0x12"}
.CE
.PP
Define a procedure that computes an
.QW interesting
mathematical function:

Changes to generic/tclAssembly.c.

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 * The instructions must be in ascending order by numeric operation code.
 */

static const unsigned char NonThrowingByteCodes[] = {
    INST_PUSH1, INST_PUSH4, INST_POP, INST_DUP,			/* 1-4 */
    INST_JUMP1, INST_JUMP4,					/* 34-35 */
    INST_END_CATCH, INST_PUSH_RESULT, INST_PUSH_RETURN_CODE,	/* 70-72 */

    INST_LIST,							/* 79 */
    INST_OVER,							/* 95 */
    INST_PUSH_RETURN_OPTIONS,					/* 108 */
    INST_REVERSE,						/* 126 */
    INST_NOP,							/* 132 */
    INST_STR_MAP,						/* 143 */
    INST_STR_FIND,						/* 144 */






>







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 * The instructions must be in ascending order by numeric operation code.
 */

static const unsigned char NonThrowingByteCodes[] = {
    INST_PUSH1, INST_PUSH4, INST_POP, INST_DUP,			/* 1-4 */
    INST_JUMP1, INST_JUMP4,					/* 34-35 */
    INST_END_CATCH, INST_PUSH_RESULT, INST_PUSH_RETURN_CODE,	/* 70-72 */
    INST_STR_EQ, INST_STR_NEQ, INST_STR_CMP, INST_STR_LEN,	/* 73-76 */
    INST_LIST,							/* 79 */
    INST_OVER,							/* 95 */
    INST_PUSH_RETURN_OPTIONS,					/* 108 */
    INST_REVERSE,						/* 126 */
    INST_NOP,							/* 132 */
    INST_STR_MAP,						/* 143 */
    INST_STR_FIND,						/* 144 */

Changes to generic/tclBasic.c.

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    }

#if defined(_WIN32) && !defined(_WIN64)
    if (sizeof(time_t) != 4) {
	/*NOTREACHED*/
	Tcl_Panic("<time.h> is not compatible with MSVC");
    }
    if ((TclOffset(Tcl_StatBuf,st_atime) != 32)
	    || (TclOffset(Tcl_StatBuf,st_ctime) != 40)) {
	/*NOTREACHED*/
	Tcl_Panic("<sys/stat.h> is not compatible with MSVC");
    }
#endif

    if (cancelTableInitialized == 0) {
	Tcl_MutexLock(&cancelLock);






|
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    }

#if defined(_WIN32) && !defined(_WIN64)
    if (sizeof(time_t) != 4) {
	/*NOTREACHED*/
	Tcl_Panic("<time.h> is not compatible with MSVC");
    }
    if ((offsetof(Tcl_StatBuf,st_atime) != 32)
	    || (offsetof(Tcl_StatBuf,st_ctime) != 40)) {
	/*NOTREACHED*/
	Tcl_Panic("<sys/stat.h> is not compatible with MSVC");
    }
#endif

    if (cancelTableInitialized == 0) {
	Tcl_MutexLock(&cancelLock);

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				 * minus 1 byte. */
    unsigned char bytes[1];	/* The array of bytes. The actual size of this
				 * field depends on the 'allocated' field
				 * above. */
} ByteArray;

#define BYTEARRAY_SIZE(len) \
		((TclOffset(ByteArray, bytes) + (len)))
#define GET_BYTEARRAY(irPtr) ((ByteArray *) (irPtr)->twoPtrValue.ptr1)
#define SET_BYTEARRAY(irPtr, baPtr) \
		(irPtr)->twoPtrValue.ptr1 = (baPtr)
 
int
TclIsPureByteArray(
    Tcl_Obj * objPtr)






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				 * minus 1 byte. */
    unsigned char bytes[1];	/* The array of bytes. The actual size of this
				 * field depends on the 'allocated' field
				 * above. */
} ByteArray;

#define BYTEARRAY_SIZE(len) \
		(offsetof(ByteArray, bytes) + (len))
#define GET_BYTEARRAY(irPtr) ((ByteArray *) (irPtr)->twoPtrValue.ptr1)
#define SET_BYTEARRAY(irPtr, baPtr) \
		(irPtr)->twoPtrValue.ptr1 = (baPtr)
 
int
TclIsPureByteArray(
    Tcl_Obj * objPtr)

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    size_t refCount;		/* Number of mem_headers referencing this
				 * tag. */
    char string[1];		/* Actual size of string will be as large as
				 * needed for actual tag. This must be the
				 * last field in the structure. */
} MemTag;

#define TAG_SIZE(bytesInString) ((TclOffset(MemTag, string) + 1) + bytesInString)

static MemTag *curTagPtr = NULL;/* Tag to use in all future mem_headers (set
				 * by "memory tag" command). */

/*
 * One of the following structures is allocated just before each dynamically
 * allocated chunk of memory, both to record information about the chunk and






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    size_t refCount;		/* Number of mem_headers referencing this
				 * tag. */
    char string[1];		/* Actual size of string will be as large as
				 * needed for actual tag. This must be the
				 * last field in the structure. */
} MemTag;

#define TAG_SIZE(bytesInString) ((offsetof(MemTag, string) + 1) + bytesInString)

static MemTag *curTagPtr = NULL;/* Tag to use in all future mem_headers (set
				 * by "memory tag" command). */

/*
 * One of the following structures is allocated just before each dynamically
 * allocated chunk of memory, both to record information about the chunk and

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    /*
     * Create a new variable if appropriate.
     */

    if (create || (name == NULL)) {
	localVar = procPtr->numCompiledLocals;
	localPtr = Tcl_Alloc(TclOffset(CompiledLocal, name) + nameBytes + 1);
	if (procPtr->firstLocalPtr == NULL) {
	    procPtr->firstLocalPtr = procPtr->lastLocalPtr = localPtr;
	} else {
	    procPtr->lastLocalPtr->nextPtr = localPtr;
	    procPtr->lastLocalPtr = localPtr;
	}
	localPtr->nextPtr = NULL;






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    /*
     * Create a new variable if appropriate.
     */

    if (create || (name == NULL)) {
	localVar = procPtr->numCompiledLocals;
	localPtr = Tcl_Alloc(offsetof(CompiledLocal, name) + nameBytes + 1);
	if (procPtr->firstLocalPtr == NULL) {
	    procPtr->firstLocalPtr = procPtr->lastLocalPtr = localPtr;
	} else {
	    procPtr->lastLocalPtr->nextPtr = localPtr;
	    procPtr->lastLocalPtr = localPtr;
	}
	localPtr->nextPtr = NULL;

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    } while (0)
 
/*
 * These variable-access macros have to coincide with those in tclVar.c
 */

#define VarHashGetValue(hPtr) \
    ((Var *) ((char *)hPtr - TclOffset(VarInHash, entry)))

static inline Var *
VarHashCreateVar(
    TclVarHashTable *tablePtr,
    Tcl_Obj *key,
    int *newPtr)
{






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    } while (0)
 
/*
 * These variable-access macros have to coincide with those in tclVar.c
 */

#define VarHashGetValue(hPtr) \
    ((Var *) ((char *)hPtr - offsetof(VarInHash, entry)))

static inline Var *
VarHashCreateVar(
    TclVarHashTable *tablePtr,
    Tcl_Obj *key,
    int *newPtr)
{

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    Tcl_HashEntry *hPtr;
    size_t size, allocsize;

    allocsize = size = strlen(string) + 1;
    if (size < sizeof(hPtr->key)) {
	allocsize = sizeof(hPtr->key);
    }
    hPtr = Tcl_Alloc(TclOffset(Tcl_HashEntry, key) + allocsize);
    memcpy(hPtr->key.string, string, size);
    Tcl_SetHashValue(hPtr, NULL);
    return hPtr;
}
 
/*
 *----------------------------------------------------------------------






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    Tcl_HashEntry *hPtr;
    size_t size, allocsize;

    allocsize = size = strlen(string) + 1;
    if (size < sizeof(hPtr->key)) {
	allocsize = sizeof(hPtr->key);
    }
    hPtr = Tcl_Alloc(offsetof(Tcl_HashEntry, key) + allocsize);
    memcpy(hPtr->key.string, string, size);
    Tcl_SetHashValue(hPtr, NULL);
    return hPtr;
}
 
/*
 *----------------------------------------------------------------------

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    				/* Next buffer in chain. */
    char buf[1];		/* Placeholder for real buffer. The real
				 * buffer occuppies this space + bufSize-1
				 * bytes. This must be the last field in the
				 * structure. */
} ChannelBuffer;

#define CHANNELBUFFER_HEADER_SIZE	TclOffset(ChannelBuffer, buf)

/*
 * How much extra space to allocate in buffer to hold bytes from previous
 * buffer (when converting to UTF-8) or to hold bytes that will go to next
 * buffer (when converting from UTF-8).
 */







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    				/* Next buffer in chain. */
    char buf[1];		/* Placeholder for real buffer. The real
				 * buffer occuppies this space + bufSize-1
				 * bytes. This must be the last field in the
				 * structure. */
} ChannelBuffer;

#define CHANNELBUFFER_HEADER_SIZE	offsetof(ChannelBuffer, buf)

/*
 * How much extra space to allocate in buffer to hold bytes from previous
 * buffer (when converting to UTF-8) or to hold bytes that will go to next
 * buffer (when converting from UTF-8).
 */

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#endif
#ifdef NO_STRING_H
#include "../compat/string.h"
#else
#include <string.h>
#endif
#if defined(STDC_HEADERS) || defined(__STDC__) || defined(__C99__FUNC__) \
     || defined(__cplusplus) || defined(_MSC_VER)
#include <stddef.h>
#else
typedef int ptrdiff_t;
#endif

/*
 * Ensure WORDS_BIGENDIAN is defined correctly:
................................................................................
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclDivOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileDivOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclLessOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileLessOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclLeqOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileLeqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclGreaterOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileGreaterOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclGeqOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileGeqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclEqOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileEqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclStreqOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileStreqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);

MODULE_SCOPE int	TclCompileAssembleCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
................................................................................
#    ifdef NO_ISNAN
#	 define TclIsNaN(d)	((d) != (d))
#    else
#	 define TclIsNaN(d)	(isnan(d))
#    endif
#endif

/*
 * ----------------------------------------------------------------------
 * Macro to use to find the offset of a field in a structure. Computes number
 * of bytes from beginning of structure to a given field.
 */

#ifdef offsetof
#define TclOffset(type, field) (offsetof(type, field))
#else
#define TclOffset(type, field) (((char *) &((type *) 0)->field))
#endif

/*
 *----------------------------------------------------------------
 * Inline version of Tcl_GetCurrentNamespace and Tcl_GetGlobalNamespace.
 */







|







 







<
<
<



<
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<



<
<
<



<
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<



<
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<



<
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<







 







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....
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4823


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#endif
#ifdef NO_STRING_H
#include "../compat/string.h"
#else
#include <string.h>
#endif
#if defined(STDC_HEADERS) || defined(__STDC__) || defined(__C99__FUNC__) \
     || defined(__cplusplus) || defined(_MSC_VER) || defined(__ICC)
#include <stddef.h>
#else
typedef int ptrdiff_t;
#endif

/*
 * Ensure WORDS_BIGENDIAN is defined correctly:
................................................................................
			    struct CompileEnv *envPtr);
MODULE_SCOPE int	TclDivOpCmd(void *clientData,
			    Tcl_Interp *interp, int objc,
			    Tcl_Obj *const objv[]);
MODULE_SCOPE int	TclCompileDivOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);



MODULE_SCOPE int	TclCompileLessOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);



MODULE_SCOPE int	TclCompileLeqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);



MODULE_SCOPE int	TclCompileGreaterOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);



MODULE_SCOPE int	TclCompileGeqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);



MODULE_SCOPE int	TclCompileEqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);



MODULE_SCOPE int	TclCompileStreqOpCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);

MODULE_SCOPE int	TclCompileAssembleCmd(Tcl_Interp *interp,
			    Tcl_Parse *parsePtr, Command *cmdPtr,
			    struct CompileEnv *envPtr);
................................................................................
#    ifdef NO_ISNAN
#	 define TclIsNaN(d)	((d) != (d))
#    else
#	 define TclIsNaN(d)	(isnan(d))
#    endif
#endif

/* Workaround for platforms missing offsetof(), e.g. VC++ 6.0 */





#ifndef offsetof


#   define offsetof(type, field) ((size_t) ((char *) &((type *) 0)->field))
#endif

/*
 *----------------------------------------------------------------
 * Inline version of Tcl_GetCurrentNamespace and Tcl_GetGlobalNamespace.
 */

Changes to generic/tclOOMethod.c.

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125
126
127
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/*
 * Helper macros (derived from things private to tclVar.c)
 */

#define TclVarTable(contextNs) \
    ((Tcl_HashTable *) (&((Namespace *) (contextNs))->varTable))
#define TclVarHashGetValue(hPtr) \
    ((Tcl_Var) ((char *)hPtr - TclOffset(VarInHash, entry)))
 
/*
 * ----------------------------------------------------------------------
 *
 * Tcl_NewInstanceMethod --
 *
 *	Attach a method to an object instance.






|







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118
119
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121
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123
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128
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130
131
/*
 * Helper macros (derived from things private to tclVar.c)
 */

#define TclVarTable(contextNs) \
    ((Tcl_HashTable *) (&((Namespace *) (contextNs))->varTable))
#define TclVarHashGetValue(hPtr) \
    ((Tcl_Var) ((char *)hPtr - offsetof(VarInHash, entry)))
 
/*
 * ----------------------------------------------------------------------
 *
 * Tcl_NewInstanceMethod --
 *
 *	Attach a method to an object instance.

Changes to generic/tclProc.c.

630
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635
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641
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643
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	    localPtr = localPtr->nextPtr;
	} else {
	    /*
	     * Allocate an entry in the runtime procedure frame's array of
	     * local variables for the argument.
	     */

	    localPtr = Tcl_Alloc(TclOffset(CompiledLocal, name) + fieldValues[0]->length +1);
	    if (procPtr->firstLocalPtr == NULL) {
		procPtr->firstLocalPtr = procPtr->lastLocalPtr = localPtr;
	    } else {
		procPtr->lastLocalPtr->nextPtr = localPtr;
		procPtr->lastLocalPtr = localPtr;
	    }
	    localPtr->nextPtr = NULL;






|







630
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	    localPtr = localPtr->nextPtr;
	} else {
	    /*
	     * Allocate an entry in the runtime procedure frame's array of
	     * local variables for the argument.
	     */

	    localPtr = Tcl_Alloc(offsetof(CompiledLocal, name) + fieldValues[0]->length +1);
	    if (procPtr->firstLocalPtr == NULL) {
		procPtr->firstLocalPtr = procPtr->lastLocalPtr = localPtr;
	    } else {
		procPtr->lastLocalPtr->nextPtr = localPtr;
		procPtr->lastLocalPtr = localPtr;
	    }
	    localPtr->nextPtr = NULL;

Changes to generic/tclTest.c.

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    if (resVarInfo->var) {
        HashVarFree(resVarInfo->var);
    }
    Tcl_Free(vInfoPtr);
}

#define TclVarHashGetValue(hPtr) \
    ((Var *) ((char *)hPtr - TclOffset(VarInHash, entry)))

static Tcl_Var
MyCompiledVarFetch(
    Tcl_Interp *interp,
    Tcl_ResolvedVarInfo *vinfoPtr)
{
    MyResolvedVarInfo *resVarInfo = (MyResolvedVarInfo *) vinfoPtr;






|







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    if (resVarInfo->var) {
        HashVarFree(resVarInfo->var);
    }
    Tcl_Free(vInfoPtr);
}

#define TclVarHashGetValue(hPtr) \
    ((Var *) ((char *)hPtr - offsetof(VarInHash, entry)))

static Tcl_Var
MyCompiledVarFetch(
    Tcl_Interp *interp,
    Tcl_ResolvedVarInfo *vinfoPtr)
{
    MyResolvedVarInfo *resVarInfo = (MyResolvedVarInfo *) vinfoPtr;

Changes to generic/tclTrace.c.

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		break;
	    }
	}
	command = TclGetStringFromObj(objv[5], &commandLength);
	length = commandLength;
	if ((enum traceOptions) optionIndex == TRACE_ADD) {
	    TraceCommandInfo *tcmdPtr = Tcl_Alloc(
		    TclOffset(TraceCommandInfo, command) + 1 + length);

	    tcmdPtr->flags = flags;
	    tcmdPtr->stepTrace = NULL;
	    tcmdPtr->startLevel = 0;
	    tcmdPtr->startCmd = NULL;
	    tcmdPtr->length = length;
	    tcmdPtr->refCount = 1;
................................................................................
	    }
	}

	command = TclGetStringFromObj(objv[5], &commandLength);
	length = commandLength;
	if ((enum traceOptions) optionIndex == TRACE_ADD) {
	    TraceCommandInfo *tcmdPtr = Tcl_Alloc(
		    TclOffset(TraceCommandInfo, command) + 1 + length);

	    tcmdPtr->flags = flags;
	    tcmdPtr->stepTrace = NULL;
	    tcmdPtr->startLevel = 0;
	    tcmdPtr->startCmd = NULL;
	    tcmdPtr->length = length;
	    tcmdPtr->refCount = 1;
................................................................................
		break;
	    }
	}
	command = TclGetStringFromObj(objv[5], &commandLength);
	length = commandLength;
	if ((enum traceOptions) optionIndex == TRACE_ADD) {
	    CombinedTraceVarInfo *ctvarPtr = Tcl_Alloc(
		    TclOffset(CombinedTraceVarInfo, traceCmdInfo.command)
		    + 1 + length);

	    ctvarPtr->traceCmdInfo.flags = flags;
#ifndef TCL_REMOVE_OBSOLETE_TRACES
	    if (objv[0] == NULL) {
		ctvarPtr->traceCmdInfo.flags |= TCL_TRACE_OLD_STYLE;
	    }






|







 







|







 







|







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		break;
	    }
	}
	command = TclGetStringFromObj(objv[5], &commandLength);
	length = commandLength;
	if ((enum traceOptions) optionIndex == TRACE_ADD) {
	    TraceCommandInfo *tcmdPtr = Tcl_Alloc(
		    offsetof(TraceCommandInfo, command) + 1 + length);

	    tcmdPtr->flags = flags;
	    tcmdPtr->stepTrace = NULL;
	    tcmdPtr->startLevel = 0;
	    tcmdPtr->startCmd = NULL;
	    tcmdPtr->length = length;
	    tcmdPtr->refCount = 1;
................................................................................
	    }
	}

	command = TclGetStringFromObj(objv[5], &commandLength);
	length = commandLength;
	if ((enum traceOptions) optionIndex == TRACE_ADD) {
	    TraceCommandInfo *tcmdPtr = Tcl_Alloc(
		    offsetof(TraceCommandInfo, command) + 1 + length);

	    tcmdPtr->flags = flags;
	    tcmdPtr->stepTrace = NULL;
	    tcmdPtr->startLevel = 0;
	    tcmdPtr->startCmd = NULL;
	    tcmdPtr->length = length;
	    tcmdPtr->refCount = 1;
................................................................................
		break;
	    }
	}
	command = TclGetStringFromObj(objv[5], &commandLength);
	length = commandLength;
	if ((enum traceOptions) optionIndex == TRACE_ADD) {
	    CombinedTraceVarInfo *ctvarPtr = Tcl_Alloc(
		    offsetof(CombinedTraceVarInfo, traceCmdInfo.command)
		    + 1 + length);

	    ctvarPtr->traceCmdInfo.flags = flags;
#ifndef TCL_REMOVE_OBSOLETE_TRACES
	    if (objv[0] == NULL) {
		ctvarPtr->traceCmdInfo.flags |= TCL_TRACE_OLD_STYLE;
	    }

Changes to generic/tclVar.c.

41
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48
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55
			    Tcl_Obj *key, int *newPtr);
static inline Var *	VarHashFirstVar(TclVarHashTable *tablePtr,
			    Tcl_HashSearch *searchPtr);
static inline Var *	VarHashNextVar(Tcl_HashSearch *searchPtr);
static inline void	CleanupVar(Var *varPtr, Var *arrayPtr);

#define VarHashGetValue(hPtr) \
    ((Var *) ((char *)hPtr - TclOffset(VarInHash, entry)))

/*
 * NOTE: VarHashCreateVar increments the recount of its key argument.
 * All callers that will call Tcl_DecrRefCount on that argument must
 * call Tcl_IncrRefCount on it before passing it in.  This requirement
 * can bubble up to callers of callers .... etc.
 */






|







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45
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47
48
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			    Tcl_Obj *key, int *newPtr);
static inline Var *	VarHashFirstVar(TclVarHashTable *tablePtr,
			    Tcl_HashSearch *searchPtr);
static inline Var *	VarHashNextVar(Tcl_HashSearch *searchPtr);
static inline void	CleanupVar(Var *varPtr, Var *arrayPtr);

#define VarHashGetValue(hPtr) \
    ((Var *) ((char *)hPtr - offsetof(VarInHash, entry)))

/*
 * NOTE: VarHashCreateVar increments the recount of its key argument.
 * All callers that will call Tcl_DecrRefCount on that argument must
 * call Tcl_IncrRefCount on it before passing it in.  This requirement
 * can bubble up to callers of callers .... etc.
 */