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Always turn off hyphenation; it makes .\" way too many mistakes in technical documents. .if n .ad l .nh .SH "NAME" B::Op_private \- OP op_private flag definitions .SH "SYNOPSIS" .IX Header "SYNOPSIS" .Vb 1 \& use B::Op_private; \& \& # flag details for bit 7 of OP_AELEM\*(Aqs op_private: \& my $name = $B::Op_private::bits{aelem}{7}; # OPpLVAL_INTRO \& my $value = $B::Op_private::defines{$name}; # 128 \& my $label = $B::Op_private::labels{$name}; # LVINTRO \& \& # the bit field at bits 5..6 of OP_AELEM\*(Aqs op_private: \& my $bf = $B::Op_private::bits{aelem}{6}; \& my $mask = $bf\->{bitmask}; # etc .Ve .SH "DESCRIPTION" .IX Header "DESCRIPTION" This module provides four global hashes: .PP .Vb 4 \& %B::Op_private::bits \& %B::Op_private::defines \& %B::Op_private::labels \& %B::Op_private::ops_using .Ve .PP which contain information about the per-op meanings of the bits in the op_private field. .ie n .SS "%bits" .el .SS "\f(CW%bits\fP" .IX Subsection "%bits" This is indexed by op name and then bit number (0..7). For single bit flags, it returns the name of the define (if any) for that bit: .PP .Vb 1 \& $B::Op_private::bits{aelem}{7} eq \*(AqOPpLVAL_INTRO\*(Aq; .Ve .PP For bit fields, it returns a hash ref containing details about the field. The same reference will be returned for all bit positions that make up the bit field; so for example these both return the same hash ref: .PP .Vb 2 \& $bitfield = $B::Op_private::bits{aelem}{5}; \& $bitfield = $B::Op_private::bits{aelem}{6}; .Ve .PP The general format of this hash ref is .PP .Vb 5 \& { \& # The bit range and mask; these are always present. \& bitmin => 5, \& bitmax => 6, \& bitmask => 0x60, \& \& # (The remaining keys are optional) \& \& # The names of any defines that were requested: \& mask_def => \*(AqOPpFOO_MASK\*(Aq, \& baseshift_def => \*(AqOPpFOO_SHIFT\*(Aq, \& bitcount_def => \*(AqOPpFOO_BITS\*(Aq, \& \& # If present, Concise etc will display the value with a \*(AqFOO=\*(Aq \& # prefix. If it equals \*(Aq\-\*(Aq, then Concise will treat the bit \& # field as raw bits and not try to interpret it. \& label => \*(AqFOO\*(Aq, \& \& # If present, specifies the names of some defines and the \& # display labels that are used to assign meaning to particu\- \& # lar integer values within the bit field; e.g. 3 is dis\- \& # played as \*(AqC\*(Aq. \& enum => [ qw( \& 1 OPpFOO_A A \& 2 OPpFOO_B B \& 3 OPpFOO_C C \& )], \& \& }; .Ve .ie n .SS "%defines" .el .SS "\f(CW%defines\fP" .IX Subsection "%defines" This gives the value of every \f(CW\*(C`OPp\*(C'\fR define, e.g. .PP .Vb 1 \& $B::Op_private::defines{OPpLVAL_INTRO} == 128; .Ve .ie n .SS "%labels" .el .SS "\f(CW%labels\fP" .IX Subsection "%labels" This gives the short display label for each define, as used by \f(CW\*(C`B::Concise\*(C'\fR and \f(CW\*(C`perl \-Dx\*(C'\fR, e.g. .PP .Vb 1 \& $B::Op_private::labels{OPpLVAL_INTRO} eq \*(AqLVINTRO\*(Aq; .Ve .PP If the label equals '\-', then Concise will treat the bit as a raw bit and not try to display it symbolically. .ie n .SS "%ops_using" .el .SS "\f(CW%ops_using\fP" .IX Subsection "%ops_using" For each define, this gives a reference to an array of op names that use the flag. .PP .Vb 1 \& @ops_using_lvintro = @{ $B::Op_private::ops_using{OPp_LVAL_INTRO} }; .Ve