gas/doc/c-bfin.texi - binutils-gdb - Git at Google

 @c Copyright (C) 2005-2021 Free Software Foundation, Inc.
 @c This is part of the GAS manual.
 @c For copying conditions, see the file as.texinfo.
 @c man end

 @ifset GENERIC
 @page
 @node Blackfin-Dependent
 @chapter Blackfin Dependent Features
 @end ifset

 @ifclear GENERIC
 @node Machine Dependencies
 @chapter Blackfin Dependent Features
 @end ifclear

 @cindex Blackfin support
 @menu
 * Blackfin Options::		Blackfin Options
 * Blackfin Syntax::		Blackfin Syntax
 * Blackfin Directives::		Blackfin Directives
 @end menu

 @node Blackfin Options
 @section Options
 @cindex Blackfin options (none)
 @cindex options for Blackfin (none)

 @c man begin OPTIONS
 @table @gcctabopt

 @cindex @code{-mcpu=} command-line option, Blackfin
 @item -mcpu=@var{processor}@r{[}-@var{sirevision}@r{]}
 This option specifies the target processor.  The optional @var{sirevision}
 is not used in assembler.  It's here such that GCC can easily pass down its
 @code{-mcpu=} option.  The assembler will issue an
 error message if an attempt is made to assemble an instruction which
 will not execute on the target processor.  The following processor names are
 recognized:
 @code{bf504},
 @code{bf506},
 @code{bf512},
 @code{bf514},
 @code{bf516},
 @code{bf518},
 @code{bf522},
 @code{bf523},
 @code{bf524},
 @code{bf525},
 @code{bf526},
 @code{bf527},
 @code{bf531},
 @code{bf532},
 @code{bf533},
 @code{bf534},
 @code{bf535} (not implemented yet),
 @code{bf536},
 @code{bf537},
 @code{bf538},
 @code{bf539},
 @code{bf542},
 @code{bf542m},
 @code{bf544},
 @code{bf544m},
 @code{bf547},
 @code{bf547m},
 @code{bf548},
 @code{bf548m},
 @code{bf549},
 @code{bf549m},
 @code{bf561},
 and
 @code{bf592}.

 @cindex @code{-mfdpic} command-line option, Blackfin
 @item -mfdpic
 Assemble for the FDPIC ABI.

 @cindex @code{-mno-fdpic} command-line option, Blackfin
 @cindex @code{-mnopic} command-line option, Blackfin
 @item -mno-fdpic
 @itemx -mnopic
 Disable -mfdpic.
 @end table
 @c man end

 @node Blackfin Syntax
 @section Syntax
 @cindex Blackfin syntax
 @cindex syntax, Blackfin

 @table @code
 @item Special Characters
 Assembler input is free format and may appear anywhere on the line.
 One instruction may extend across multiple lines or more than one
 instruction may appear on the same line.  White space (space, tab,
 comments or newline) may appear anywhere between tokens.  A token must
 not have embedded spaces.  Tokens include numbers, register names,
 keywords, user identifiers, and also some multicharacter special
 symbols like "+=", "/*" or "||".

 Comments are introduced by the @samp{#} character and extend to the
 end of the current line.  If the @samp{#} appears as the first
 character of a line, the whole line is treated as a comment, but in
 this case the line can also be a logical line number directive
 (@pxref{Comments}) or a preprocessor control command
 (@pxref{Preprocessing}).

 @item Instruction Delimiting
 A semicolon must terminate every instruction.  Sometimes a complete
 instruction will consist of more than one operation.  There are two
 cases where this occurs.  The first is when two general operations
 are combined.  Normally a comma separates the different parts, as in

 @smallexample
 a0= r3.h * r2.l, a1 = r3.l * r2.h ;
 @end smallexample

 The second case occurs when a general instruction is combined with one
 or two memory references for joint issue.  The latter portions are
 set off by a "||" token.

 @smallexample
 a0 = r3.h * r2.l || r1 = [p3++] || r4 = [i2++];
 @end smallexample

 Multiple instructions can occur on the same line.  Each must be
 terminated by a semicolon character.

 @item Register Names

 The assembler treats register names and instruction keywords in a case
 insensitive manner.  User identifiers are case sensitive.  Thus, R3.l,
 R3.L, r3.l and r3.L are all equivalent input to the assembler.

 Register names are reserved and may not be used as program identifiers.

 Some operations (such as "Move Register") require a register pair.
 Register pairs are always data registers and are denoted using a colon,
 eg., R3:2.  The larger number must be written firsts.  Note that the
 hardware only supports odd-even pairs, eg., R7:6, R5:4, R3:2, and R1:0.

 Some instructions (such as --SP (Push Multiple)) require a group of
 adjacent registers.  Adjacent registers are denoted in the syntax by
 the range enclosed in parentheses and separated by a colon, eg., (R7:3).
 Again, the larger number appears first.

 Portions of a particular register may be individually specified.  This
 is written with a dot (".") following the register name and then a
 letter denoting the desired portion.  For 32-bit registers, ".H"
 denotes the most significant ("High") portion.  ".L" denotes the
 least-significant portion.  The subdivisions of the 40-bit registers
 are described later.

 @item Accumulators
 The set of 40-bit registers A1 and A0 that normally contain data that
 is being manipulated.  Each accumulator can be accessed in four ways.

 @table @code
 @item one 40-bit register
 The register will be referred to as A1 or A0.
 @item one 32-bit register
 The registers are designated as A1.W or A0.W.
 @item two 16-bit registers
 The registers are designated as A1.H, A1.L, A0.H or A0.L.
 @item one 8-bit register
 The registers are designated as A1.X or A0.X for the bits that
 extend beyond bit 31.
 @end table

 @item Data Registers
 The set of 32-bit registers (R0, R1, R2, R3, R4, R5, R6 and R7) that
 normally contain data for manipulation.  These are abbreviated as
 D-register or Dreg.  Data registers can be accessed as 32-bit registers
 or as two independent 16-bit registers.  The least significant 16 bits
 of each register is called the "low" half and is designated with ".L"
 following the register name.  The most significant 16 bits are called
 the "high" half and is designated with ".H" following the name.

 @smallexample
    R7.L, r2.h, r4.L, R0.H
 @end smallexample

 @item Pointer Registers
 The set of 32-bit registers (P0, P1, P2, P3, P4, P5, SP and FP) that
 normally contain byte addresses of data structures.  These are
 abbreviated as P-register or Preg.

 @smallexample
 p2, p5, fp, sp
 @end smallexample

 @item Stack Pointer SP
 The stack pointer contains the 32-bit address of the last occupied
 byte location in the stack.  The stack grows by decrementing the
 stack pointer.

 @item Frame Pointer FP
 The frame pointer contains the 32-bit address of the previous frame
 pointer in the stack.  It is located at the top of a frame.

 @item Loop Top
 LT0 and LT1.  These registers contain the 32-bit address of the top of
 a zero overhead loop.

 @item Loop Count
 LC0 and LC1.  These registers contain the 32-bit counter of the zero
 overhead loop executions.

 @item Loop Bottom
 LB0 and LB1.  These registers contain the 32-bit address of the bottom
 of a zero overhead loop.

 @item Index Registers
 The set of 32-bit registers (I0, I1, I2, I3) that normally contain byte
 addresses of data structures.  Abbreviated I-register or Ireg.

 @item Modify Registers
 The set of 32-bit registers (M0, M1, M2, M3) that normally contain
 offset values that are added and subtracted to one of the index
 registers.  Abbreviated as Mreg.

 @item Length Registers
 The set of 32-bit registers (L0, L1, L2, L3) that normally contain the
 length in bytes of the circular buffer.  Abbreviated as Lreg.  Clear
 the Lreg to disable circular addressing for the corresponding Ireg.

 @item Base Registers
 The set of 32-bit registers (B0, B1, B2, B3) that normally contain the
 base address in bytes of the circular buffer.  Abbreviated as Breg.

 @item Floating Point
 The Blackfin family has no hardware floating point but the .float
 directive generates ieee floating point numbers for use with software
 floating point libraries.

 @item Blackfin Opcodes
 For detailed information on the Blackfin machine instruction set, see
 the Blackfin Processor Instruction Set Reference.

 @end table

 @node Blackfin Directives
 @section Directives
 @cindex Blackfin directives
 @cindex directives, Blackfin

 The following directives are provided for compatibility with the VDSP assembler.

 @table @code
 @item .byte2
 Initializes a two byte data object.

 This maps to the @code{.short} directive.
 @item .byte4
 Initializes a four byte data object.

 This maps to the @code{.int} directive.
 @item .db
 Initializes a single byte data object.

 This directive is a synonym for @code{.byte}.
 @item .dw
 Initializes a two byte data object.

 This directive is a synonym for @code{.byte2}.
 @item .dd
 Initializes a four byte data object.

 This directive is a synonym for @code{.byte4}.
 @item .var
 Define and initialize a 32 bit data object.
 @end table
	@c Copyright (C) 2005-2021 Free Software Foundation, Inc.
	@c This is part of the GAS manual.
	@c For copying conditions, see the file as.texinfo.
	@c man end

	@ifset GENERIC
	@page
	@node Blackfin-Dependent
	@chapter Blackfin Dependent Features
	@end ifset

	@ifclear GENERIC
	@node Machine Dependencies
	@chapter Blackfin Dependent Features
	@end ifclear

	@cindex Blackfin support
	@menu
	* Blackfin Options:: Blackfin Options
	* Blackfin Syntax:: Blackfin Syntax
	* Blackfin Directives:: Blackfin Directives
	@end menu

	@node Blackfin Options
	@section Options
	@cindex Blackfin options (none)
	@cindex options for Blackfin (none)

	@c man begin OPTIONS
	@table @gcctabopt

	@cindex @code{-mcpu=} command-line option, Blackfin
	@item -mcpu=@var{processor}@r{[}-@var{sirevision}@r{]}
	This option specifies the target processor. The optional @var{sirevision}
	is not used in assembler. It's here such that GCC can easily pass down its
	@code{-mcpu=} option. The assembler will issue an
	error message if an attempt is made to assemble an instruction which
	will not execute on the target processor. The following processor names are
	recognized:
	@code{bf504},
	@code{bf506},
	@code{bf512},
	@code{bf514},
	@code{bf516},
	@code{bf518},
	@code{bf522},
	@code{bf523},
	@code{bf524},
	@code{bf525},
	@code{bf526},
	@code{bf527},
	@code{bf531},
	@code{bf532},
	@code{bf533},
	@code{bf534},
	@code{bf535} (not implemented yet),
	@code{bf536},
	@code{bf537},
	@code{bf538},
	@code{bf539},
	@code{bf542},
	@code{bf542m},
	@code{bf544},
	@code{bf544m},
	@code{bf547},
	@code{bf547m},
	@code{bf548},
	@code{bf548m},
	@code{bf549},
	@code{bf549m},
	@code{bf561},
	and
	@code{bf592}.

	@cindex @code{-mfdpic} command-line option, Blackfin
	@item -mfdpic
	Assemble for the FDPIC ABI.

	@cindex @code{-mno-fdpic} command-line option, Blackfin
	@cindex @code{-mnopic} command-line option, Blackfin
	@item -mno-fdpic
	@itemx -mnopic
	Disable -mfdpic.
	@end table
	@c man end

	@node Blackfin Syntax
	@section Syntax
	@cindex Blackfin syntax
	@cindex syntax, Blackfin

	@table @code
	@item Special Characters
	Assembler input is free format and may appear anywhere on the line.
	One instruction may extend across multiple lines or more than one
	instruction may appear on the same line. White space (space, tab,
	comments or newline) may appear anywhere between tokens. A token must
	not have embedded spaces. Tokens include numbers, register names,
	keywords, user identifiers, and also some multicharacter special
	symbols like "+=", "/*" or "\|\|".

	Comments are introduced by the @samp{#} character and extend to the
	end of the current line. If the @samp{#} appears as the first
	character of a line, the whole line is treated as a comment, but in
	this case the line can also be a logical line number directive
	(@pxref{Comments}) or a preprocessor control command
	(@pxref{Preprocessing}).

	@item Instruction Delimiting
	A semicolon must terminate every instruction. Sometimes a complete
	instruction will consist of more than one operation. There are two
	cases where this occurs. The first is when two general operations
	are combined. Normally a comma separates the different parts, as in

	@smallexample
	a0= r3.h * r2.l, a1 = r3.l * r2.h ;
	@end smallexample

	The second case occurs when a general instruction is combined with one
	or two memory references for joint issue. The latter portions are
	set off by a "\|\|" token.

	@smallexample
	a0 = r3.h * r2.l \|\| r1 = [p3++] \|\| r4 = [i2++];
	@end smallexample

	Multiple instructions can occur on the same line. Each must be
	terminated by a semicolon character.

	@item Register Names

	The assembler treats register names and instruction keywords in a case
	insensitive manner. User identifiers are case sensitive. Thus, R3.l,
	R3.L, r3.l and r3.L are all equivalent input to the assembler.

	Register names are reserved and may not be used as program identifiers.

	Some operations (such as "Move Register") require a register pair.
	Register pairs are always data registers and are denoted using a colon,
	eg., R3:2. The larger number must be written firsts. Note that the
	hardware only supports odd-even pairs, eg., R7:6, R5:4, R3:2, and R1:0.

	Some instructions (such as --SP (Push Multiple)) require a group of
	adjacent registers. Adjacent registers are denoted in the syntax by
	the range enclosed in parentheses and separated by a colon, eg., (R7:3).
	Again, the larger number appears first.

	Portions of a particular register may be individually specified. This
	is written with a dot (".") following the register name and then a
	letter denoting the desired portion. For 32-bit registers, ".H"
	denotes the most significant ("High") portion. ".L" denotes the
	least-significant portion. The subdivisions of the 40-bit registers
	are described later.

	@item Accumulators
	The set of 40-bit registers A1 and A0 that normally contain data that
	is being manipulated. Each accumulator can be accessed in four ways.

	@table @code
	@item one 40-bit register
	The register will be referred to as A1 or A0.
	@item one 32-bit register
	The registers are designated as A1.W or A0.W.
	@item two 16-bit registers
	The registers are designated as A1.H, A1.L, A0.H or A0.L.
	@item one 8-bit register
	The registers are designated as A1.X or A0.X for the bits that
	extend beyond bit 31.
	@end table

	@item Data Registers
	The set of 32-bit registers (R0, R1, R2, R3, R4, R5, R6 and R7) that
	normally contain data for manipulation. These are abbreviated as
	D-register or Dreg. Data registers can be accessed as 32-bit registers
	or as two independent 16-bit registers. The least significant 16 bits
	of each register is called the "low" half and is designated with ".L"
	following the register name. The most significant 16 bits are called
	the "high" half and is designated with ".H" following the name.

	@smallexample
	R7.L, r2.h, r4.L, R0.H
	@end smallexample

	@item Pointer Registers
	The set of 32-bit registers (P0, P1, P2, P3, P4, P5, SP and FP) that
	normally contain byte addresses of data structures. These are
	abbreviated as P-register or Preg.

	@smallexample
	p2, p5, fp, sp
	@end smallexample

	@item Stack Pointer SP
	The stack pointer contains the 32-bit address of the last occupied
	byte location in the stack. The stack grows by decrementing the
	stack pointer.

	@item Frame Pointer FP
	The frame pointer contains the 32-bit address of the previous frame
	pointer in the stack. It is located at the top of a frame.

	@item Loop Top
	LT0 and LT1. These registers contain the 32-bit address of the top of
	a zero overhead loop.

	@item Loop Count
	LC0 and LC1. These registers contain the 32-bit counter of the zero
	overhead loop executions.

	@item Loop Bottom
	LB0 and LB1. These registers contain the 32-bit address of the bottom
	of a zero overhead loop.

	@item Index Registers
	The set of 32-bit registers (I0, I1, I2, I3) that normally contain byte
	addresses of data structures. Abbreviated I-register or Ireg.

	@item Modify Registers
	The set of 32-bit registers (M0, M1, M2, M3) that normally contain
	offset values that are added and subtracted to one of the index
	registers. Abbreviated as Mreg.

	@item Length Registers
	The set of 32-bit registers (L0, L1, L2, L3) that normally contain the
	length in bytes of the circular buffer. Abbreviated as Lreg. Clear
	the Lreg to disable circular addressing for the corresponding Ireg.

	@item Base Registers
	The set of 32-bit registers (B0, B1, B2, B3) that normally contain the
	base address in bytes of the circular buffer. Abbreviated as Breg.

	@item Floating Point
	The Blackfin family has no hardware floating point but the .float
	directive generates ieee floating point numbers for use with software
	floating point libraries.

	@item Blackfin Opcodes
	For detailed information on the Blackfin machine instruction set, see
	the Blackfin Processor Instruction Set Reference.

	@end table

	@node Blackfin Directives
	@section Directives
	@cindex Blackfin directives
	@cindex directives, Blackfin

	The following directives are provided for compatibility with the VDSP assembler.

	@table @code
	@item .byte2
	Initializes a two byte data object.

	This maps to the @code{.short} directive.
	@item .byte4
	Initializes a four byte data object.

	This maps to the @code{.int} directive.
	@item .db
	Initializes a single byte data object.

	This directive is a synonym for @code{.byte}.
	@item .dw
	Initializes a two byte data object.

	This directive is a synonym for @code{.byte2}.
	@item .dd
	Initializes a four byte data object.

	This directive is a synonym for @code{.byte4}.
	@item .var
	Define and initialize a 32 bit data object.
	@end table