staging: fbtft: add SPDX identifiers

[linux/fpc-iii.git] / arch / c6x / lib / divu.S

;;  Copyright 2010  Free Software Foundation, Inc.
;;  Contributed by Bernd Schmidt <bernds@codesourcery.com>.
;;
;; This program is free software; you can redistribute it and/or modify
;; it under the terms of the GNU General Public License as published by
;; the Free Software Foundation; either version 2 of the License, or
;; (at your option) any later version.
;;
;; This program is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
;; GNU General Public License for more details.
;;
;; You should have received a copy of the GNU General Public License
;; along with this program; if not, write to the Free Software
;; Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.

#include <linux/linkage.h>

        ;; ABI considerations for the divide functions
        ;; The following registers are call-used:
        ;; __c6xabi_divi A0,A1,A2,A4,A6,B0,B1,B2,B4,B5
        ;; __c6xabi_divu A0,A1,A2,A4,A6,B0,B1,B2,B4
        ;; __c6xabi_remi A1,A2,A4,A5,A6,B0,B1,B2,B4
        ;; __c6xabi_remu A1,A4,A5,A7,B0,B1,B2,B4
        ;;
        ;; In our implementation, divu and remu are leaf functions,
        ;; while both divi and remi call into divu.
        ;; A0 is not clobbered by any of the functions.
        ;; divu does not clobber B2 either, which is taken advantage of
        ;; in remi.
        ;; divi uses B5 to hold the original return address during
        ;; the call to divu.
        ;; remi uses B2 and A5 to hold the input values during the
        ;; call to divu.  It stores B3 in on the stack.

        .text
ENTRY(__c6xabi_divu)
        ;; We use a series of up to 31 subc instructions.  First, we find
        ;; out how many leading zero bits there are in the divisor.  This
        ;; gives us both a shift count for aligning (shifting) the divisor
        ;; to the, and the number of times we have to execute subc.

        ;; At the end, we have both the remainder and most of the quotient
        ;; in A4.  The top bit of the quotient is computed first and is
        ;; placed in A2.

        ;; Return immediately if the dividend is zero.
         mv     .s2x    A4, B1
   [B1]  lmbd   .l2     1, B4, B1
|| [!B1] b      .s2     B3      ; RETURN A
|| [!B1] mvk    .d2     1, B4
         mv     .l1x    B1, A6
||       shl    .s2     B4, B1, B4

        ;; The loop performs a maximum of 28 steps, so we do the
        ;; first 3 here.
         cmpltu .l1x    A4, B4, A2
   [!A2] sub    .l1x    A4, B4, A4
||       shru   .s2     B4, 1, B4
||       xor    .s1     1, A2, A2

         shl    .s1     A2, 31, A2
|| [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1

        ;; RETURN A may happen here (note: must happen before the next branch)
_divu_loop:
         cmpgt  .l2     B1, 7, B0
|| [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
|| [B0]  b      .s1     _divu_loop
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
   [B1]  subc   .l1x    A4,B4,A4
|| [B1]  add    .s2     -1, B1, B1
        ;; loop backwards branch happens here

         ret    .s2     B3
||       mvk    .s1     32, A1
         sub    .l1     A1, A6, A6
         shl    .s1     A4, A6, A4
         shru   .s1     A4, 1, A4
||       sub    .l1     A6, 1, A6
         or     .l1     A2, A4, A4
         shru   .s1     A4, A6, A4
         nop
ENDPROC(__c6xabi_divu)