353 lines
14 KiB
Groff
353 lines
14 KiB
Groff
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'\"
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'\" Copyright (c) 1996-1997 Sun Microsystems, Inc.
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'\"
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'\" See the file "license.terms" for information on usage and redistribution
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'\" of this file, and for a DISCLAIMER OF ALL WARRANTIES.
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'\"
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.TH Tcl_Obj 3 8.5 Tcl "Tcl Library Procedures"
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.so man.macros
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.BS
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.SH NAME
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Tcl_NewObj, Tcl_DuplicateObj, Tcl_IncrRefCount, Tcl_DecrRefCount, Tcl_IsShared, Tcl_InvalidateStringRep \- manipulate Tcl values
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.SH SYNOPSIS
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.nf
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\fB#include <tcl.h>\fR
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.sp
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Tcl_Obj *
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\fBTcl_NewObj\fR()
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.sp
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Tcl_Obj *
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\fBTcl_DuplicateObj\fR(\fIobjPtr\fR)
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.sp
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\fBTcl_IncrRefCount\fR(\fIobjPtr\fR)
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.sp
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\fBTcl_DecrRefCount\fR(\fIobjPtr\fR)
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.sp
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int
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\fBTcl_IsShared\fR(\fIobjPtr\fR)
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.sp
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\fBTcl_InvalidateStringRep\fR(\fIobjPtr\fR)
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.SH ARGUMENTS
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.AS Tcl_Obj *objPtr
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.AP Tcl_Obj *objPtr in
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Points to a value;
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must have been the result of a previous call to \fBTcl_NewObj\fR.
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.BE
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.SH INTRODUCTION
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.PP
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This man page presents an overview of Tcl values (called \fBTcl_Obj\fRs for
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historical reasons) and how they are used.
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It also describes generic procedures for managing Tcl values.
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These procedures are used to create and copy values,
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and increment and decrement the count of references (pointers) to values.
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The procedures are used in conjunction with ones
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that operate on specific types of values such as
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\fBTcl_GetIntFromObj\fR and \fBTcl_ListObjAppendElement\fR.
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The individual procedures are described along with the data structures
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they manipulate.
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.PP
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Tcl's \fIdual-ported\fR values provide a general-purpose mechanism
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for storing and exchanging Tcl values.
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They largely replace the use of strings in Tcl.
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For example, they are used to store variable values,
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command arguments, command results, and scripts.
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Tcl values behave like strings but also hold an internal representation
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that can be manipulated more efficiently.
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For example, a Tcl list is now represented as a value
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that holds the list's string representation
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as well as an array of pointers to the values for each list element.
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Dual-ported values avoid most runtime type conversions.
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They also improve the speed of many operations
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since an appropriate representation is immediately available.
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The compiler itself uses Tcl values to
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cache the instruction bytecodes resulting from compiling scripts.
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.PP
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The two representations are a cache of each other and are computed lazily.
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That is, each representation is only computed when necessary,
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it is computed from the other representation,
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and, once computed, it is saved.
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In addition, a change in one representation invalidates the other one.
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As an example, a Tcl program doing integer calculations can
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operate directly on a variable's internal machine integer
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representation without having to constantly convert
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between integers and strings.
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Only when it needs a string representing the variable's value,
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say to print it,
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will the program regenerate the string representation from the integer.
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Although values contain an internal representation,
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their semantics are defined in terms of strings:
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an up-to-date string can always be obtained,
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and any change to the value will be reflected in that string
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when the value's string representation is fetched.
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Because of this representation invalidation and regeneration,
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it is dangerous for extension writers to access
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\fBTcl_Obj\fR fields directly.
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It is better to access Tcl_Obj information using
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procedures like \fBTcl_GetStringFromObj\fR and \fBTcl_GetString\fR.
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.PP
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Values are allocated on the heap
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and are referenced using a pointer to their \fBTcl_Obj\fR structure.
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Values are shared as much as possible.
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This significantly reduces storage requirements
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because some values such as long lists are very large.
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Also, most Tcl values are only read and never modified.
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This is especially true for procedure arguments,
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which can be shared between the caller and the called procedure.
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Assignment and argument binding is done by
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simply assigning a pointer to the value.
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Reference counting is used to determine when it is safe to
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reclaim a value's storage.
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.PP
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Tcl values are typed.
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A value's internal representation is controlled by its type.
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Several types are predefined in the Tcl core
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including integer, double, list, and bytecode.
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Extension writers can extend the set of types
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by defining their own \fBTcl_ObjType\fR structs.
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.SH "THE TCL_OBJ STRUCTURE"
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.PP
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Each Tcl value is represented by a \fBTcl_Obj\fR structure
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which is defined as follows.
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.PP
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.CS
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typedef struct Tcl_Obj {
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int \fIrefCount\fR;
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char *\fIbytes\fR;
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int \fIlength\fR;
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const Tcl_ObjType *\fItypePtr\fR;
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union {
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long \fIlongValue\fR;
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double \fIdoubleValue\fR;
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void *\fIotherValuePtr\fR;
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Tcl_WideInt \fIwideValue\fR;
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struct {
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void *\fIptr1\fR;
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void *\fIptr2\fR;
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} \fItwoPtrValue\fR;
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struct {
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void *\fIptr\fR;
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unsigned long \fIvalue\fR;
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} \fIptrAndLongRep\fR;
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} \fIinternalRep\fR;
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} \fBTcl_Obj\fR;
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.CE
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.PP
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The \fIbytes\fR and the \fIlength\fR members together hold
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a value's UTF-8 string representation,
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which is a \fIcounted string\fR not containing null bytes (UTF-8 null
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characters should be encoded as a two byte sequence: 192, 128.)
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\fIbytes\fR points to the first byte of the string representation.
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The \fIlength\fR member gives the number of bytes.
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The byte array must always have a null byte after the last data byte,
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at offset \fIlength\fR;
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this allows string representations
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to be treated as conventional null-terminated C strings.
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C programs use \fBTcl_GetStringFromObj\fR and \fBTcl_GetString\fR to get
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a value's string representation.
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If \fIbytes\fR is NULL,
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the string representation is invalid.
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.PP
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A value's type manages its internal representation.
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The member \fItypePtr\fR points to the Tcl_ObjType structure
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that describes the type.
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If \fItypePtr\fR is NULL,
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the internal representation is invalid.
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.PP
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The \fIinternalRep\fR union member holds
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a value's internal representation.
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This is either a (long) integer, a double-precision floating-point number,
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a pointer to a value containing additional information
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needed by the value's type to represent the value, a Tcl_WideInt
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integer, two arbitrary pointers, or a pair made up of an unsigned long
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integer and a pointer.
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.PP
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The \fIrefCount\fR member is used to tell when it is safe to free
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a value's storage.
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It holds the count of active references to the value.
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Maintaining the correct reference count is a key responsibility
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of extension writers.
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Reference counting is discussed below
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in the section \fBSTORAGE MANAGEMENT OF VALUES\fR.
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.PP
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Although extension writers can directly access
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the members of a Tcl_Obj structure,
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it is much better to use the appropriate procedures and macros.
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For example, extension writers should never
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read or update \fIrefCount\fR directly;
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they should use macros such as
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\fBTcl_IncrRefCount\fR and \fBTcl_IsShared\fR instead.
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.PP
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A key property of Tcl values is that they hold two representations.
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A value typically starts out containing only a string representation:
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it is untyped and has a NULL \fItypePtr\fR.
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A value containing an empty string or a copy of a specified string
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is created using \fBTcl_NewObj\fR or \fBTcl_NewStringObj\fR respectively.
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A value's string value is gotten with
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\fBTcl_GetStringFromObj\fR or \fBTcl_GetString\fR
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and changed with \fBTcl_SetStringObj\fR.
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If the value is later passed to a procedure like \fBTcl_GetIntFromObj\fR
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that requires a specific internal representation,
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the procedure will create one and set the value's \fItypePtr\fR.
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The internal representation is computed from the string representation.
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A value's two representations are duals of each other:
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changes made to one are reflected in the other.
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For example, \fBTcl_ListObjReplace\fR will modify a value's
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internal representation and the next call to \fBTcl_GetStringFromObj\fR
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or \fBTcl_GetString\fR will reflect that change.
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.PP
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Representations are recomputed lazily for efficiency.
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A change to one representation made by a procedure
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such as \fBTcl_ListObjReplace\fR is not reflected immediately
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in the other representation.
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Instead, the other representation is marked invalid
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so that it is only regenerated if it is needed later.
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Most C programmers never have to be concerned with how this is done
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and simply use procedures such as \fBTcl_GetBooleanFromObj\fR or
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\fBTcl_ListObjIndex\fR.
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Programmers that implement their own value types
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must check for invalid representations
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and mark representations invalid when necessary.
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The procedure \fBTcl_InvalidateStringRep\fR is used
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to mark a value's string representation invalid and to
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free any storage associated with the old string representation.
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.PP
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Values usually remain one type over their life,
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but occasionally a value must be converted from one type to another.
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For example, a C program might build up a string in a value
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with repeated calls to \fBTcl_AppendToObj\fR,
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and then call \fBTcl_ListObjIndex\fR to extract a list element from
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the value.
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The same value holding the same string value
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can have several different internal representations
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at different times.
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Extension writers can also force a value to be converted from one type
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to another using the \fBTcl_ConvertToType\fR procedure.
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Only programmers that create new value types need to be concerned
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about how this is done.
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A procedure defined as part of the value type's implementation
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creates a new internal representation for a value
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and changes its \fItypePtr\fR.
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See the man page for \fBTcl_RegisterObjType\fR
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to see how to create a new value type.
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.SH "EXAMPLE OF THE LIFETIME OF A VALUE"
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.PP
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As an example of the lifetime of a value,
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consider the following sequence of commands:
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.PP
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.CS
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\fBset x 123\fR
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.CE
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.PP
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This assigns to \fIx\fR an untyped value whose
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\fIbytes\fR member points to \fB123\fR and \fIlength\fR member contains 3.
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The value's \fItypePtr\fR member is NULL.
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.PP
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.CS
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\fBputs "x is $x"\fR
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.CE
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.PP
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\fIx\fR's string representation is valid (since \fIbytes\fR is non-NULL)
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and is fetched for the command.
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.PP
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.CS
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\fBincr x\fR
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.CE
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.PP
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The \fBincr\fR command first gets an integer from \fIx\fR's value
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by calling \fBTcl_GetIntFromObj\fR.
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This procedure checks whether the value is already an integer value.
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Since it is not, it converts the value
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by setting the value's internal representation
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to the integer \fB123\fR
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and setting the value's \fItypePtr\fR
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to point to the integer Tcl_ObjType structure.
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Both representations are now valid.
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\fBincr\fR increments the value's integer internal representation
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then invalidates its string representation
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(by calling \fBTcl_InvalidateStringRep\fR)
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since the string representation
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no longer corresponds to the internal representation.
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.PP
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.CS
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\fBputs "x is now $x"\fR
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.CE
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.PP
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The string representation of \fIx\fR's value is needed
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and is recomputed.
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The string representation is now \fB124\fR
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and both representations are again valid.
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.SH "STORAGE MANAGEMENT OF VALUES"
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.PP
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Tcl values are allocated on the heap and are shared as much as possible
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to reduce storage requirements.
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Reference counting is used to determine when a value is
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no longer needed and can safely be freed.
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A value just created by \fBTcl_NewObj\fR or \fBTcl_NewStringObj\fR
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has \fIrefCount\fR 0.
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The macro \fBTcl_IncrRefCount\fR increments the reference count
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when a new reference to the value is created.
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The macro \fBTcl_DecrRefCount\fR decrements the count
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when a reference is no longer needed and,
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if the value's reference count drops to zero, frees its storage.
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A value shared by different code or data structures has
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\fIrefCount\fR greater than 1.
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Incrementing a value's reference count ensures that
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it will not be freed too early or have its value change accidentally.
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.PP
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As an example, the bytecode interpreter shares argument values
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between calling and called Tcl procedures to avoid having to copy values.
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It assigns the call's argument values to the procedure's
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formal parameter variables.
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In doing so, it calls \fBTcl_IncrRefCount\fR to increment
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the reference count of each argument since there is now a new
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reference to it from the formal parameter.
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When the called procedure returns,
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the interpreter calls \fBTcl_DecrRefCount\fR to decrement
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each argument's reference count.
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When a value's reference count drops less than or equal to zero,
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\fBTcl_DecrRefCount\fR reclaims its storage.
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Most command procedures do not have to be concerned about
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reference counting since they use a value's value immediately
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and do not retain a pointer to the value after they return.
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However, if they do retain a pointer to a value in a data structure,
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they must be careful to increment its reference count
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since the retained pointer is a new reference.
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.PP
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Command procedures that directly modify values
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such as those for \fBlappend\fR and \fBlinsert\fR must be careful to
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copy a shared value before changing it.
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They must first check whether the value is shared
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by calling \fBTcl_IsShared\fR.
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If the value is shared they must copy the value
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by using \fBTcl_DuplicateObj\fR;
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this returns a new duplicate of the original value
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that has \fIrefCount\fR 0.
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If the value is not shared,
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the command procedure
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.QW "owns"
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the value and can safely modify it directly.
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For example, the following code appears in the command procedure
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that implements \fBlinsert\fR.
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This procedure modifies the list value passed to it in \fIobjv[1]\fR
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by inserting \fIobjc-3\fR new elements before \fIindex\fR.
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.PP
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.CS
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listPtr = objv[1];
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if (\fBTcl_IsShared\fR(listPtr)) {
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listPtr = \fBTcl_DuplicateObj\fR(listPtr);
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}
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result = Tcl_ListObjReplace(interp, listPtr, index, 0,
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(objc-3), &(objv[3]));
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.CE
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.PP
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As another example, \fBincr\fR's command procedure
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must check whether the variable's value is shared before
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incrementing the integer in its internal representation.
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If it is shared, it needs to duplicate the value
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in order to avoid accidentally changing values in other data structures.
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.SH "SEE ALSO"
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Tcl_ConvertToType(3), Tcl_GetIntFromObj(3), Tcl_ListObjAppendElement(3), Tcl_ListObjIndex(3), Tcl_ListObjReplace(3), Tcl_RegisterObjType(3)
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.SH KEYWORDS
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internal representation, value, value creation, value type,
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reference counting, string representation, type conversion
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