llvm-gcc-4.2/gcc/config/h8300/genmova.sh - llvm-archive - Git at Google

 #!/bin/sh
 # Generate mova.md, a file containing patterns that can be implemented
 # using the h8sx mova instruction.

 echo ";; -*- buffer-read-only: t -*-"
 echo ";; Generated automatically from genmova.sh"

 # Loop over modes for the source operand (the index).  Only 8-bit and
 # 16-bit indices are allowed.
 for s in QI HI; do

   # Set $src to the operand syntax for this size of index.
   case $s in
     QI) src=%X1.b;;
     HI) src=%T1.w;;
   esac

   # A match_operand for the source.
   operand="(match_operand:$s 1 \"h8300_dst_operand\" \"0,rQ\")"

   # Loop over the destination register's mode.  The QI and HI versions use
   # the same instructions as the SI ones, they just ignore the upper bits
   # of the result.
   for d in QI HI SI; do

     # If the destination is larger than the source, include a
     # zero_extend/plus pattern.  We could also match zero extensions
     # of memory without the plus, but it's not any smaller or faster
     # than separate insns.
     case $d:$s in
       SI:QI | SI:HI | HI:QI)
 	cat <<EOF
 (define_insn ""
   [(set (match_operand:$d 0 "register_operand" "=r,r")
 	(plus:$d (zero_extend:$d $operand)
 		 (match_operand:$d 2 "immediate_operand" "i,i")))]
   "TARGET_H8300SX"
   "mova/b.l @(%o2,$src),%S0"
   [(set_attr "length_table" "mova")
    (set_attr "cc" "none")])

 EOF
 	;;
     esac

     # Loop over the shift amount.
     for shift in 1 2; do
       case $shift in
 	1) opsize=w mult=2;;
 	2) opsize=l mult=4;;
       esac

       # Calculate the mask of bits that will be nonzero after the source
       # has been extended and shifted.
       case $s:$shift in
 	QI:1) mask=510;;
 	QI:2) mask=1020;;
 	HI:1) mask=131070;;
 	HI:2) mask=262140;;
       esac

       # There doesn't seem to be a well-established canonical form for
       # some of the patterns we need.  Emit both shift and multiplication
       # patterns.
       for form in mult ashift; do
 	case $form in
 	  mult) amount=$mult;;
 	  ashift) amount=$shift;;
 	esac

 	case $d:$s in
 	  # If the source and destination are the same size, we can treat
 	  # mova as a sort of multiply-add instruction.
 	  QI:QI | HI:HI)
 	    cat <<EOF
 (define_insn ""
   [(set (match_operand:$d 0 "register_operand" "=r,r")
 	(plus:$d ($form:$d $operand
 			   (const_int $amount))
 		 (match_operand:$d 2 "immediate_operand" "i,i")))]
   "TARGET_H8300SX"
   "mova/$opsize.l @(%o2,$src),%S0"
   [(set_attr "length_table" "mova")
    (set_attr "cc" "none")])

 EOF
 	    ;;

 	  # Handle the cases where the source is smaller than the
 	  # destination.  Sometimes combine will keep the extension,
 	  # sometimes it will use an AND.
 	  SI:QI | SI:HI | HI:QI)

 	    # Emit the forms that use zero_extend.
 	    cat <<EOF
 (define_insn ""
   [(set (match_operand:$d 0 "register_operand" "=r,r")
 	($form:$d (zero_extend:$d $operand)
 		  (const_int $amount)))]
   "TARGET_H8300SX"
   "mova/$opsize.l @(0,$src),%S0"
   [(set_attr "length_table" "mova_zero")
    (set_attr "cc" "none")])

 (define_insn ""
   [(set (match_operand:$d 0 "register_operand" "=r,r")
 	(plus:$d ($form:$d (zero_extend:$d $operand)
 			   (const_int $amount))
 		 (match_operand:$d 2 "immediate_operand" "i,i")))]
   "TARGET_H8300SX"
   "mova/$opsize.l @(%o2,$src),%S0"
   [(set_attr "length_table" "mova")
    (set_attr "cc" "none")])

 EOF

 	    # Now emit the forms that use AND.  When the index is a register,
 	    # these forms are effectively $d-mode operations: the index will
 	    # be a $d-mode REG or SUBREG.  When the index is a memory
 	    # location, we will have a paradoxical subreg such as:
 	    #
 	    #	(and:SI (mult:SI (subreg:SI (mem:QI ...) 0)
 	    #			 (const_int 4))
 	    #		(const_int 1020))
 	    #
 	    # Match the two case separately: a $d-mode register_operand
 	    # or a $d-mode subreg of an $s-mode memory_operand.  Match the
 	    # memory form first since register_operand accepts mem subregs
 	    # before reload.
 	    memory="(match_operand:$s 1 \"memory_operand\" \"m\")"
 	    memory="(subreg:$d $memory 0)"
 	    register="(match_operand:$d 1 \"register_operand\" \"0\")"
 	    for paradoxical in "$memory" "$register"; do
 	      cat <<EOF
 (define_insn ""
   [(set (match_operand:$d 0 "register_operand" "=r")
 	(and:$d ($form:$d $paradoxical
 			  (const_int $amount))
 		(const_int $mask)))]
   "TARGET_H8300SX"
   "mova/$opsize.l @(0,$src),%S0"
   [(set_attr "length_table" "mova_zero")
    (set_attr "cc" "none")])

 (define_insn ""
   [(set (match_operand:$d 0 "register_operand" "=r")
 	(plus:$d (and:$d ($form:$d $paradoxical
 				   (const_int $amount))
 			 (const_int $mask))
 		 (match_operand:$d 2 "immediate_operand" "i")))]
   "TARGET_H8300SX"
   "mova/$opsize.l @(%o2,$src),%S0"
   [(set_attr "length_table" "mova")
    (set_attr "cc" "none")])

 EOF
 	      done
 	    ;;
 	esac
       done
     done
   done
 done
	#!/bin/sh
	# Generate mova.md, a file containing patterns that can be implemented
	# using the h8sx mova instruction.

	echo ";; -- buffer-read-only: t --"
	echo ";; Generated automatically from genmova.sh"

	# Loop over modes for the source operand (the index). Only 8-bit and
	# 16-bit indices are allowed.
	for s in QI HI; do

	# Set $src to the operand syntax for this size of index.
	case $s in
	QI) src=%X1.b;;
	HI) src=%T1.w;;
	esac

	# A match_operand for the source.
	operand="(match_operand:$s 1 \"h8300_dst_operand\" \"0,rQ\")"

	# Loop over the destination register's mode. The QI and HI versions use
	# the same instructions as the SI ones, they just ignore the upper bits
	# of the result.
	for d in QI HI SI; do

	# If the destination is larger than the source, include a
	# zero_extend/plus pattern. We could also match zero extensions
	# of memory without the plus, but it's not any smaller or faster
	# than separate insns.
	case $d:$s in
	SI:QI \| SI:HI \| HI:QI)
	cat <<EOF
	(define_insn ""
	[(set (match_operand:$d 0 "register_operand" "=r,r")
	(plus:$d (zero_extend:$d $operand)
	(match_operand:$d 2 "immediate_operand" "i,i")))]
	"TARGET_H8300SX"
	"mova/b.l @(%o2,$src),%S0"
	[(set_attr "length_table" "mova")
	(set_attr "cc" "none")])

	EOF
	;;
	esac

	# Loop over the shift amount.
	for shift in 1 2; do
	case $shift in
	1) opsize=w mult=2;;
	2) opsize=l mult=4;;
	esac

	# Calculate the mask of bits that will be nonzero after the source
	# has been extended and shifted.
	case $s:$shift in
	QI:1) mask=510;;
	QI:2) mask=1020;;
	HI:1) mask=131070;;
	HI:2) mask=262140;;
	esac

	# There doesn't seem to be a well-established canonical form for
	# some of the patterns we need. Emit both shift and multiplication
	# patterns.
	for form in mult ashift; do
	case $form in
	mult) amount=$mult;;
	ashift) amount=$shift;;
	esac

	case $d:$s in
	# If the source and destination are the same size, we can treat
	# mova as a sort of multiply-add instruction.
	QI:QI \| HI:HI)
	cat <<EOF
	(define_insn ""
	[(set (match_operand:$d 0 "register_operand" "=r,r")
	(plus:$d ($form:$d $operand
	(const_int $amount))
	(match_operand:$d 2 "immediate_operand" "i,i")))]
	"TARGET_H8300SX"
	"mova/$opsize.l @(%o2,$src),%S0"
	[(set_attr "length_table" "mova")
	(set_attr "cc" "none")])

	EOF
	;;

	# Handle the cases where the source is smaller than the
	# destination. Sometimes combine will keep the extension,
	# sometimes it will use an AND.
	SI:QI \| SI:HI \| HI:QI)

	# Emit the forms that use zero_extend.
	cat <<EOF
	(define_insn ""
	[(set (match_operand:$d 0 "register_operand" "=r,r")
	($form:$d (zero_extend:$d $operand)
	(const_int $amount)))]
	"TARGET_H8300SX"
	"mova/$opsize.l @(0,$src),%S0"
	[(set_attr "length_table" "mova_zero")
	(set_attr "cc" "none")])

	(define_insn ""
	[(set (match_operand:$d 0 "register_operand" "=r,r")
	(plus:$d ($form:$d (zero_extend:$d $operand)
	(const_int $amount))
	(match_operand:$d 2 "immediate_operand" "i,i")))]
	"TARGET_H8300SX"
	"mova/$opsize.l @(%o2,$src),%S0"
	[(set_attr "length_table" "mova")
	(set_attr "cc" "none")])

	EOF

	# Now emit the forms that use AND. When the index is a register,
	# these forms are effectively $d-mode operations: the index will
	# be a $d-mode REG or SUBREG. When the index is a memory
	# location, we will have a paradoxical subreg such as:
	#
	# (and:SI (mult:SI (subreg:SI (mem:QI ...) 0)
	# (const_int 4))
	# (const_int 1020))
	#
	# Match the two case separately: a $d-mode register_operand
	# or a $d-mode subreg of an $s-mode memory_operand. Match the
	# memory form first since register_operand accepts mem subregs
	# before reload.
	memory="(match_operand:$s 1 \"memory_operand\" \"m\")"
	memory="(subreg:$d $memory 0)"
	register="(match_operand:$d 1 \"register_operand\" \"0\")"
	for paradoxical in "$memory" "$register"; do
	cat <<EOF
	(define_insn ""
	[(set (match_operand:$d 0 "register_operand" "=r")
	(and:$d ($form:$d $paradoxical
	(const_int $amount))
	(const_int $mask)))]
	"TARGET_H8300SX"
	"mova/$opsize.l @(0,$src),%S0"
	[(set_attr "length_table" "mova_zero")
	(set_attr "cc" "none")])

	(define_insn ""
	[(set (match_operand:$d 0 "register_operand" "=r")
	(plus:$d (and:$d ($form:$d $paradoxical
	(const_int $amount))
	(const_int $mask))
	(match_operand:$d 2 "immediate_operand" "i")))]
	"TARGET_H8300SX"
	"mova/$opsize.l @(%o2,$src),%S0"
	[(set_attr "length_table" "mova")
	(set_attr "cc" "none")])

	EOF
	done
	;;
	esac
	done
	done
	done
	done