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/* fp.S. Floating point instruction set test of Or1ksim
 
   Copyright (C) 1999-2006 OpenCores
   Copyright (C) 2010 Embecosm Limited
   Copyright (C) 2010 ORSoC AB
 
   Contributors various OpenCores participants
   Contributor Jeremy Bennett 
   Contributor Julius Baxter 
 
   This file is part of OpenRISC 1000 Architectural Simulator.
 
   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 3 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, see .  */
 
 
/* ----------------------------------------------------------------------------
 * Test coverage
 *
 * At present the tests are only reasonably comprehensive for lf.add.s and
 * lf.div.s. This is intended as a template for future work, and still has
 * omissions even so.
 *
 * Basic tests are provided for all single precision floating point
 * numbers. Since Or1ksim translates these operations into host FP, there is
 * little point in testing more of the subtleties of IEEE 745.
 *
 * However in future this test could be used with OpenRISC hardware, in which
 * case exhaustive testing would be essential.
 * ------------------------------------------------------------------------- */
 
 
#include "spr-defs.h"
#include "board.h"
 
/* ----------------------------------------------------------------------------
 * Coding conventions
 *
v * A simple rising stack is provided to starting at _stack and pointed to by
 * r1. r1 points to the next free word. Only 32-bit registers may be pushed
 * onto the stack.
 *
 * Temporary labels up to 49 are reserved for macros and subroutines. Each is
 * used only once in any macro or subroutine. You can get in a serious mess if
 * you get local label clashing in macros.
 *
 * Arguments to functions are passed in r3 through r8.
 * r9 is the link (return address)
 * r11 is for returning results
 * r2 through r11 are not preserved across calls. All other registers are.
 * ------------------------------------------------------------------------- */
 
 
/* ----------------------------------------------------------------------------
 * Memory controller constants
 * ------------------------------------------------------------------------- */
 
#define MEM_RAM 0x00000000
 
/* ----------------------------------------------------------------------------
 * Floating point constants (IEEE 754)
 *
 * For the record, the single precision format has 1 sign bit, 8 exponent bits
 * and 23 fraction bits.
 *
 *   seeeeeeeefffffffffffffffffffffff
 *
 * The exponent is biased by 2^7 - 1 (i.e 127 is subtracted from the value to
 * give the actual exponent). Normalized numbers have a non-zero exponent (up
 * to 2^8 - 2) and an implicit 1 before the fraction. Thus the value
 * represented is
 *
 *   (-1)^s * 1.fffffffffffffffffffffff * 2^(eeeeeeee - (2^7 - 1))
 *
 * Special values used are:
 *
 *  Zeroes                Exponent is zero,    fraction also zero
 *  Denormalized numbers  Exponent is zero,    fraction non-zero
 *  Infinities            Exponent is 2^8 - 1, fraction is zero
 *  NaNs                  Exponent is 2^8 - 1, fraction is non-zero
 *
 * The top bit of the fraction in a NaN is often used to indicate the type of
 * NaN. If 1, it is a "quiet" NaN, if 0 it is a "signalling" NaN. Quiet NaN's
 * are generally propagated for FP errors. Signalling NaN's can be used for
 * more unusual purposes
 *
 * In general any other bits of the NaN fraction are just propagated unchanged.
 * ------------------------------------------------------------------------- */
 
#define FP_S_P_ZERO    (0x00000000)     /* Positive zero */
#define FP_S_N_ZERO    (0x80000000)     /* Positive zero */
#define FP_S_P_INF     (0x7f800000)     /* Positive infinity */
#define FP_S_N_INF     (0xff800000)     /* Negative infinity */
#define FP_S_P_NAN     (0x7fc00000)     /* Positive qNaN */
#define FP_S_N_NAN     (0xffc00000)     /* Negative qNaN */
 
/* Some NaNs without all fraction bits set (permitted under IEEE 754) */
#define FP_S_P_NAN_B   (0x7f800001)     /* Positive NaN, not all 1s in frac */
#define FP_S_N_NAN_B   (0xff800001)     /* Negative NaN, not all 1s in frac */
 
/* Some single precision normalized numbers */
#define  FP_S_0_5      (0x3f000000)     /* +0.5 */
#define  FP_S_ONE      (0x3f800000)     /* +1.0 */
#define  FP_S_1_5      (0x3fc00000)     /* +1.5 */
#define  FP_S_TWO      (0x40000000)     /* +2.0 */
#define  FP_S_THREE    (0x40400000)     /* +3.0 */
#define  FP_S_HUGE1    (0x7e800000)     /* +1.0 * 2^+126 */
#define  FP_S_HUGE2    (0x7f000000)     /* +1.0 * 2^+127 */
#define  FP_S_N_0_5    (0xbf000000)     /* -0.5 */
#define  FP_S_N_ONE    (0xbf800000)     /* -1.0 */
#define  FP_S_N_1_5    (0xbfc00000)     /* -1.5 */
#define  FP_S_N_TWO    (0xc0000000)     /* -2.0 */
#define  FP_S_N_THREE  (0xc0400000)     /* -3.0 */
#define  FP_S_N_HUGE1  (0xfe800000)     /* -1.0 * 2^+126 */
#define  FP_S_N_HUGE2  (0xff000000)     /* -1.0 * 2^+127 */
 
/* Some denormalized numbers */
#define  FP_S_SMALL1   (0x00200000)     /* +1.0 * 2^-129 */
#define  FP_S_SMALL2   (0x00400000)     /* +1.0 * 2^-128 */
#define  FP_S_N_SMALL1 (0x80200000)     /* -1.0 * 2^-129 */
#define  FP_S_N_SMALL2 (0x80400000)     /* -1.0 * 2^-128 */
 
/* Indicator of completion */
#define  ALL_DONE     (0xdeaddead)
 
/* Logical values */
#define TRUE   1
#define FALSE  0
 
 
/* ----------------------------------------------------------------------------
 * Macro to push a register onto the stack
 *
 * r1 points to the next free slot. Push the supplied register on, then
 * advance the stack pointer.
 *
 * Arguments:
 *   reg  The register to push
 *
 * Registers modified
 *   r1
 * ------------------------------------------------------------------------- */
#define PUSH(reg)                                                        \
        l.sw    0(r1),reg               /* Push */                      ;\
        l.addi  r1,r1,4                 /* Advance the stack */
 
/* ----------------------------------------------------------------------------
 * Macro to pop a register off the stack
 *
 * r1 points to the next free slot. Decrement the stack pointer, then pop the
 * requested register.
 *
 * Arguments:
 *   reg  The register to pop
 *
 * Registers modified
 *   r1
 * ------------------------------------------------------------------------- */
#define POP(reg)                                                         \
        l.addi  r1,r1,-4                /* Decrement the stack */       ;\
        l.lws   reg,0(r1)               /* Pop */
 
/* ----------------------------------------------------------------------------
 * Macro to load a 32-bit constant into a register
 *
 * Arguments:
 *   reg  The register to load
 *   val  The value to load
 *
 * ------------------------------------------------------------------------- */
#define LOAD_CONST(reg,val)                                              \
        l.movhi reg,hi(val)                                             ;\
        l.ori   reg,reg,lo(val)
 
/* ----------------------------------------------------------------------------
 * Macro to define and load a pointer to a string
 *
 * Arguments:
 *   reg  The register to load
 *   str  The string
 *
 * ------------------------------------------------------------------------- */
#define LOAD_STR(reg,str)                                                \
        .section .rodata                                                ;\
1:                                                                      ;\
        .string str                                                     ;\
                                                                        ;\
        .section .text                                                  ;\
        l.movhi reg,hi(1b)                                              ;\
        l.ori   reg,reg,lo(1b)
 
/* ----------------------------------------------------------------------------
 * Macro to print a character
 *
 * Arguments:
 *   c  The character to print
 * ------------------------------------------------------------------------- */
#define PUTC(c)                                                          \
        l.addi  r3,r0,c                                                 ;\
        l.nop   NOP_PUTC
 
/* ----------------------------------------------------------------------------
 * Macro for recording the result of a test
 *
 * The test result is in r4. Print out the name of test indented two spaces,
 * followed by  ": ", either "OK" or "Failed" and a newline.
 *
 * Arguments:
 *   str  Textual name of the test
 *   reg  The result to test (not r2)
 *   val  Desired result of the test
 * ------------------------------------------------------------------------- */
#define CHECK_RES(str,reg,val)                                           \
        .section .rodata                                                ;\
2:                                                                      ;\
        .string str                                                     ;\
                                                                        ;\
        .section .text                                                  ;\
        PUSH (reg)                      /* Save the register to test */ ;\
                                                                        ;\
        LOAD_CONST (r3,2b)              /* Print out the string */      ;\
        l.jal   _ptest                                                  ;\
        l.nop                                                           ;\
                                                                        ;\
        LOAD_CONST(r2,val)              /* The desired result */        ;\
        POP (reg)                       /* The register to test */      ;\
        PUSH (reg)                      /* May need again later */      ;\
        l.sfeq  r2,reg                  /* Does the result match? */    ;\
        l.bf    3f                                                      ;\
        l.nop                                                           ;\
                                                                        ;\
        l.jal   _pfail                  /* Test failed */               ;\
        l.nop                                                           ;\
        POP (reg)                       /* Report the register */       ;\
        l.add   r3,r0,reg                                               ;\
        l.j     4f                                                      ;\
        l.nop   NOP_REPORT                                              ;\
3:                                                                      ;\
        POP (reg)                       /* Discard the register */      ;\
        l.jal   _pok                    /* Test succeeded */            ;\
        l.nop                                                           ;\
4:
 
/* ----------------------------------------------------------------------------
 * Macro for recording the result of a comparison
 *
 * If the flag is set print the string argument indented by 2 spaces, followed
 * by "TRUE" and a  newline, otherwise print the string argument indented by
 * two spaces, followed by "FALSE" and a newline.
 *
 * Arguments:
 *   str  Textual name of the test
 *   res  Expected result (TRUE or FALSE)
 * ------------------------------------------------------------------------- */
#define CHECK_FLAG(str,res)                                              \
        .section .rodata                                                ;\
5:                                                                      ;\
        .string str                                                     ;\
                                                                        ;\
        .section .text                                                  ;\
        l.bnf   7f                      /* Branch if result FALSE */    ;\
                                                                        ;\
        /* Branch for TRUE result */                                    ;\
        LOAD_CONST (r3,5b)              /* The string to print */       ;\
        l.jal   _ptest                                                  ;\
        l.nop                                                           ;\
                                                                        ;\
        l.addi  r2,r0,TRUE              /* Was it expected? */          ;\
        l.addi  r3,r0,res                                               ;\
        l.sfeq  r2,r3                                                   ;\
        l.bnf   6f                      /* Branch if not expected */    ;\
                                                                        ;\
        /* Sub-branch for TRUE found and expected */                    ;\
        l.jal   _ptrue                                                  ;\
        l.nop                                                           ;\
        PUTC ('\n')                                                     ;\
        l.j     9f                                                      ;\
        l.nop                                                           ;\
6:                                                                      ;\
        /* Sub-branch for TRUE found and not expected */                ;\
        l.jal   _ptrue                                                  ;\
        l.nop                                                           ;\
        l.jal   _punexpected                                            ;\
        l.nop                                                           ;\
        l.j     9f                                                      ;\
        l.nop                                                           ;\
                                                                        ;\
7:                                                                      ;\
        /* Branch for FALSE result */                                   ;\
        LOAD_CONST (r3,5b)              /* The string to print */       ;\
        l.jal   _ptest                                                  ;\
        l.nop                                                           ;\
                                                                        ;\
        l.addi  r2,r0,FALSE             /* Was it expected? */          ;\
        l.addi  r3,r0,res                                               ;\
        l.sfeq  r2,r3                                                   ;\
        l.bnf   8f                      /* Branch if not expected */    ;\
                                                                        ;\
        /* Sub-branch for FALSE found and expected */                   ;\
        l.jal   _pfalse                                                 ;\
        l.nop                                                           ;\
        PUTC ('\n')                                                     ;\
        l.j     9f                                                      ;\
        l.nop                                                           ;\
8:                                                                      ;\
        /* Sub-branch for FALSE found and not expected */               ;\
        l.jal   _pfalse                                                 ;\
        l.nop                                                           ;\
        l.jal   _punexpected                                            ;\
        l.nop                                                           ;\
9:
 
/* ----------------------------------------------------------------------------
 * Macro for setting rounding mode in FPCSR
 *
 * Arguments:
 *   rm  round mode macro from spr-defs.h
 * ------------------------------------------------------------------------- */
#define SET_RM(rm)                                               \
        l.mfspr r4, r0, SPR_FPCSR                               ;\
        /* Clear rounding mode bits */                          ;\
        l.ori   r4, r4, SPR_FPCSR_RM                            ;\
        l.xori  r4, r4, SPR_FPCSR_RM                            ;\
        /* Set desired rounding mode bits */                    ;\
        l.ori r4, r4, rm                                        ;\
        l.mtspr r0, r4, SPR_FPCSR
 
 
 
/* ----------------------------------------------------------------------------
 * Simple stack, will be pointed to by r1, which is the next empty slot
 * ------------------------------------------------------------------------- */
        .section .data
        .balign 4
        .global _stack
_stack:
        .space  0x1000,0x0
 
/* ----------------------------------------------------------------------------
 * reset exception
 * ------------------------------------------------------------------------- */
        .section .except,"ax"
 
        .org 0x100
_reset:
        l.movhi r1,hi(_stack)           /* Set up the stack */
        l.ori   r1,r1,lo(_stack)
 
        l.movhi r3,hi(start)            /* Jump to test start */
        l.ori   r3,r3,lo(start)
        l.jr    r3
        l.nop
 
        .org 0x700
illegal_insn:
        l.nop
        .section .rodata                                                ;\
1:                                                                      ;\
        .string "Illegal instruction. Enable hardware FPU.\n"           ;\
                                                                        ;\
        .section .except,"ax"                                                   ;\
        l.movhi r3,hi(1b)                                               ;\
        l.ori   r3,r3,lo(1b)
        l.jal   _puts
        l.nop
 
        .section .rodata                                                ;\
1:                                                                      ;\
        .string "Exiting.\n"                                            ;\
                                                                        ;\
        .section .except,"ax"                                                   ;\
        l.movhi r3,hi(1b)                                               ;\
        l.ori   r3,r3,lo(1b)
        l.jal   _puts
        l.nop
 
        l.addi  r3,r0,1
        l.nop   NOP_EXIT
 
 
        .section .text
/* ----------------------------------------------------------------------------
 * Subroutine to print out a string
 *
 * The string is followed by a newline
 *
 * Parameters:
 *  r3  Pointer to the string to print
 * ------------------------------------------------------------------------- */
_puts:
        l.add   r2,r0,r3                /* Copy the string pointer */
 
        /* Loop getting and printing each char until end of string */
10:
        l.lbz   r3,0(r2)
        l.sfeq  r3,r0                   /* NULL termination? */
        l.bf    11f
 
        l.addi  r2,r2,1                 /* Delay slot, move to next char */
        l.j     10b                     /* Repeat */
        l.nop   NOP_PUTC                /* Delay slot */
 
11:
        l.jr    r9                      /* Return */
        l.nop
 
/* ----------------------------------------------------------------------------
 * Subroutine to print out a test name prompt
 *
 * The string is preceded by two spaces
 *
 * Parameters:
 *  r3  Pointer to the test name to print
 * ------------------------------------------------------------------------- */
_ptest:
        PUSH(r9)                        /* Save the return address */
        PUSH(r3)                        /* Save the test name for later */
 
        LOAD_STR(r3, "  ")              /* Prefix */
        l.jal   _puts
        l.nop
 
        POP(r3)                         /* Test name */
        l.jal   _puts
        l.nop
 
        POP (r9)
        l.jr    r9
 
 
/* ----------------------------------------------------------------------------
 * Subroutine to print out "OK"
 *
 * The string is followed by a newline
 * ------------------------------------------------------------------------- */
_pok:
        PUSH(r9)                        /* Save the return address */
 
        LOAD_STR(r3, "OK\n")
        l.jal   _puts
        l.nop
 
        POP (r9)
        l.jr    r9
 
 
/* ----------------------------------------------------------------------------
 * Subroutine to print out "Failed"
 *
 * The string is followed by a ": ", which will then allow a report
 * ------------------------------------------------------------------------- */
_pfail:
        PUSH(r9)                        /* Save the return address */
 
        LOAD_STR(r3, "Failed: ")
        l.jal   _puts
        l.nop
 
        POP (r9)
        l.jr    r9
 
/* ----------------------------------------------------------------------------
 * Subroutine to print out "TRUE"
 * ------------------------------------------------------------------------- */
_ptrue:
        PUSH(r9)                        /* Save the return address */
 
        LOAD_STR(r3, "TRUE")
        l.jal   _puts
        l.nop
 
        POP (r9)
        l.jr    r9
 
 
/* ----------------------------------------------------------------------------
 * Subroutine to print out "FALSE"
 * ------------------------------------------------------------------------- */
_pfalse:
        PUSH(r9)                        /* Save the return address */
 
        LOAD_STR(r3, "FALSE")
        l.jal   _puts
        l.nop
 
        POP (r9)
        l.jr    r9
 
/* ----------------------------------------------------------------------------
 * Subroutine to print out "unexpected"
 *
 * Preceded by a space and followed by a newline
 * ------------------------------------------------------------------------- */
_punexpected:
        PUSH(r9)                        /* Save the return address */
 
        LOAD_STR(r3, " unexpected\n")
        l.jal   _puts
        l.nop
 
        POP (r9)
        l.jr    r9
 
/* ----------------------------------------------------------------------------
 * Start of tests
 * ------------------------------------------------------------------------- */
 
start:
 
/* ----------------------------------------------------------------------------
 * Test of single precision add: lf.add.s
 * ------------------------------------------------------------------------- */
 
_add_s:
        LOAD_STR (r3, "lf.add.s\n")
        l.jal   _puts
        l.nop
 
        /* Simple integer addition */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 +  0.0  =  1.0:  ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_ZERO)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + -0.0  =  1.0:  ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 +  1.0  =  2.0:  ", r4, FP_S_TWO)
 
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_ONE)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 2.0 +  1.0  =  3.0:  ", r4, FP_S_THREE)
 
        /* Fractional addition */
        LOAD_CONST (r5,FP_S_1_5)
        LOAD_CONST (r6,FP_S_1_5)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.5 +  1.5  =  3.0:  ", r4, FP_S_THREE)
 
        /* Addition with negative numbers */
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 2.0 + -1.0  =  1.0:  ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + -2.0  = -1.0:  ", r4, FP_S_N_ONE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + -1.0  = +0.0:  ", r4, FP_S_P_ZERO)
 
        /* Addition with infinities */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + +inf  = +inf:  ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + -inf  = -inf:  ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.add.s  r4,r5,r6
        CHECK_RES ("+inf + +inf  = +inf:  ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.add.s  r4,r5,r6
        CHECK_RES ("+inf + -inf  = -NaN:  ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_N_INF)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.add.s  r4,r5,r6
        CHECK_RES ("-inf + -inf  = -inf:  ", r4, FP_S_N_INF)
 
        /* Addition with NaNs */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + +NaN  = +NaN:  ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + -NaN  = -NaN:  ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.add.s  r4,r5,r6
        CHECK_RES ("+NaN + +NaN  = +NaN:  ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.add.s  r4,r5,r6
        CHECK_RES ("+NaN + -NaN  = +NaN:  ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.add.s  r4,r5,r6
        CHECK_RES ("-NaN + -NaN  = -NaN:  ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN_B)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + +sNaN = +qNaN: ", r4, 0x7fc00001)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_NAN_B)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 + -sNaN = -qNaN: ", r4, 0xffc00001)
 
        /* Addition with overflow */
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_HUGE2)
        lf.add.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127 +  1.0 * 2^127  = +inf:  ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_N_HUGE2)
        LOAD_CONST (r6,FP_S_N_HUGE2)
        lf.add.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^127 + -1.0 * 2^127  = -inf:  ", r4, FP_S_N_INF)
 
/* ----------------------------------------------------------------------------
 * Test of single precision custom instruction: lf.cust1.s
 * ------------------------------------------------------------------------- */
_cust1_s:
        LOAD_STR (r3, "lf.cust1.s\n")
        l.jal   _puts
        l.nop
 
        /* Just test that the instruction does nothing */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.cust1.s  r4,r5               /* Should do nothing */
        CHECK_RES ("l.cust1: ", r4, FP_S_ONE)
 
/* ----------------------------------------------------------------------------
 * Test of single precision divide instruction: lf.div.s
 * ------------------------------------------------------------------------- */
_div_s:
        LOAD_STR (r3, "lf.div.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer division */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 /  1.0 =  1.0: ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 2.0 /  1.0 =  2.0: ", r4, FP_S_TWO)
 
        /* Test division with fractional result */
        LOAD_CONST (r5,FP_S_THREE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 3.0 /  2.0 =  1.5: ", r4, FP_S_1_5)
 
        /* Test division of zero */
        LOAD_CONST (r5,FP_S_P_ZERO)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+0.0 /  1.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_N_ZERO)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-0.0 /  1.0 = -0.0: ", r4, FP_S_N_ZERO)
 
        /* Test signed division */
        LOAD_CONST (r5,FP_S_N_THREE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-3.0 /  2.0 = -1.5: ", r4, FP_S_N_1_5)
 
        LOAD_CONST (r5,FP_S_THREE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 3.0 / -2.0 = -1.5: ", r4, FP_S_N_1_5)
 
        LOAD_CONST (r5,FP_S_N_THREE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-3.0 / -2.0 = -1.5: ", r4, FP_S_1_5)
 
        /* Division by zero */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 / +0.0 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 / -0.0 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 / +0.0 = -inf: ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 / -0.0 = -inf: ", r4, FP_S_N_INF)
 
        /* Division with infinities */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 / +inf = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 / -inf = -0.0: ", r4, FP_S_N_ZERO)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 / +inf = -0.0: ", r4, FP_S_N_ZERO)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 / -inf = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+inf /  1.0 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_N_INF)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-inf /  1.0 = -inf: ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+inf / -1.0 = -inf: ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_N_INF)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-inf / -1.0 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+inf / +inf = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+inf / -inf = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_N_INF)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-inf / +inf = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_N_INF)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-inf / -inf = -NaN: ", r4, FP_S_N_NAN)
 
        /* Division with NaNs */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 / +NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 / -NaN = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 / +NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 / -NaN = 1NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+NaN /  1.0 = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        LOAD_CONST (r6,FP_S_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-NaN /  1.0 = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+NaN / -1.0 = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-NaN / -1.0 = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+NaN / +NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES ("+NaN / -NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-NaN / +NaN = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-NaN / -NaN = -NaN: ", r4, FP_S_N_NAN)
 
        /* Division with overflow */
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_SMALL1)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127  /  1.0 * 2^-129 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_N_HUGE2)
        LOAD_CONST (r6,FP_S_SMALL1)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^127  /  1.0 * 2^-129 = -inf: ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_N_SMALL1)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127  / -1.0 * 2^-129 = -inf: ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_N_HUGE2)
        LOAD_CONST (r6,FP_S_N_SMALL1)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^127  / -1.0 * 2^-129 = +inf: ", r4, FP_S_P_INF)
 
        /* Division with underflow */
        LOAD_CONST (r5,FP_S_SMALL1)
        LOAD_CONST (r6,FP_S_HUGE1)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^-129 /  1.0 * 2^127  = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_N_SMALL1)
        LOAD_CONST (r6,FP_S_HUGE1)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^-129 /  1.0 * 2^127  = -0.0: ", r4, FP_S_N_ZERO)
 
        LOAD_CONST (r5,FP_S_SMALL1)
        LOAD_CONST (r6,FP_S_N_HUGE1)
        lf.div.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^-129 / -1.0 * 2^127  = -0.0: ", r4, FP_S_N_ZERO)
 
        LOAD_CONST (r5,FP_S_N_SMALL1)
        LOAD_CONST (r6,FP_S_N_HUGE1)
        lf.div.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^-129 / -1.0 * 2^127  = +0.0: ", r4, FP_S_P_ZERO)
 
        /* Needs tests of normalization to denormalization */
 
/* ----------------------------------------------------------------------------
 * Test of single precision fp to integer conversion: lf.ftoi.s
 * ------------------------------------------------------------------------- */
v_ftoi_s:
        LOAD_STR (r3, "lf.ftoi.s\n")
        l.jal   _puts
        l.nop
 
        /* Integer conversion */
        LOAD_CONST (r5,FP_S_ONE)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int)  1.0          =  1:    ", r4, 0x00000001)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -1.0          = -1:    ", r4, 0xffffffff)
 
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) +0.0          =  0:    ", r4, 0x00000000)
 
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -0.0          =  0:    ", r4, 0x00000000)
 
        /* Fractional conversion (round towards zero) */
        SET_RM  (FPCSR_RM_RZ)
        LOAD_CONST (r5,FP_S_1_5)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int)  1.5          =  1:    ", r4, 0x00000001)
 
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -1.5          = -1:    ", r4, 0xffffffff)
 
        /* Conversion of values too big */
        LOAD_CONST (r5,FP_S_HUGE1)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int)  1.0 * 2^126  = 2^31: ", r4, 0x7fffffff)
 
        LOAD_CONST (r5,FP_S_N_HUGE1)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -1.0 * 2^126  = -2^31: ", r4, 0x80000000)
 
        /* Conversion of very small values */
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int)  1.0 * 2^-129 =  0:    ", r4, 0x00000000)
 
        LOAD_CONST (r5,FP_S_N_SMALL1)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -1.0 * 2^-129 =  0:    ", r4, 0x00000000)
 
        /* Just basic check of Infinity & NaN */
        LOAD_CONST (r5,FP_S_P_INF)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) +inf          = 2^31: ", r4, 0x7fffffff)
 
        LOAD_CONST (r5,FP_S_N_INF)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -inf          = -2^31: ", r4, 0x80000000)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) +NaN          = 2^31: ", r4, 0x7fffffff)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -NaN          = 2^31: ", r4, 0x7fffffff)
 
/* ----------------------------------------------------------------------------
 * Test of single precision integer to fp conversion: lf.itof.s
 * ------------------------------------------------------------------------- */
_itof_s:
        LOAD_STR (r3, "lf.itof.s\n")
        l.jal   _puts
        l.nop
 
        /* Integer conversion */
        LOAD_CONST (r5,FP_S_ONE)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(float)  1.0 =  1: ", r4, 0x00000001)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(float) -1.0 = -1: ", r4, 0xffffffff)
 
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(float) +0.0 =  0: ", r4, 0x00000000)
 
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(float) -0.0 =  0: ", r4, 0x00000000)
 
/* ----------------------------------------------------------------------------
 * Test of single precision multiply and add: lf.madd.s
 * ------------------------------------------------------------------------- */
_madd_s:
        LOAD_STR (r3, "lf.madd.s\n")
        l.jal   _puts
        l.nop
 
        /* Test of integer multiply and add */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 +  1.0 *  1.0 =  2.0: ", r4, FP_S_TWO)
 
        /* Multiply and add with fractions */
        LOAD_CONST (r4,FP_S_0_5)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 0.5 +  1.0 *  1.0 =  1.5: ", r4, FP_S_1_5)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_0_5)
        LOAD_CONST (r6,FP_S_TWO)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 +  0.5 *  2.0 =  2.0: ", r4, FP_S_TWO)
 
        /* Multiply and add with negative numbers */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 + -1.0 *  2.0 = -1.0: ", r4, FP_S_N_ONE)
 
        LOAD_CONST (r4,FP_S_N_TWO)
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_0_5)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-2.0 +  2.0 *  0.5 = -1.0: ", r4, FP_S_N_ONE)
 
        LOAD_CONST (r4,FP_S_N_0_5)
        LOAD_CONST (r5,FP_S_N_0_5)
        LOAD_CONST (r6,FP_S_THREE)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-0.5 + -0.5 *  3.0 = -2.0: ", r4, FP_S_N_TWO)
 
        /* Multiply and add with zeros (more needed) */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("+0.0 + +0.0 * +0.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        LOAD_CONST (r6,FP_S_N_ZERO)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-0.0 + +0.0 * -0.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        LOAD_CONST (r6,FP_S_N_ZERO)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-0.0 + -0.0 * -0.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r4,FP_S_N_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-1.0 +  1.0 *  1.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        /* Multiply and add with infinities (more needed) */
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("+inf +  1.0 *  1.0 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 +  1.0 * +inf = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("+inf +  1.0 * +inf = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-inf +  1.0 *  1.0 = -inf: ", r4, FP_S_N_INF)
 
        /* Multiply and add with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("+NaN +  1.0 *  1.0 = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 +  1.0 * +NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("+NaN +  1.0 * +NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES ("-NaN +  1.0 *  1.0 = -NaN: ", r4, FP_S_N_NAN)
 
        /* Multiply and add with overflow (more needed) */
        SET_RM  (FPCSR_RM_RIP)
        LOAD_CONST (r4,FP_S_HUGE2)
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_ONE)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127  +  1.0 * 2^127  *  1.0 = +inf: ",
                   r4, FP_S_P_INF)
 
        SET_RM  (FPCSR_RM_RIN)
        LOAD_CONST (r4,FP_S_HUGE2)
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_SMALL1)
        lf.madd.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127  +  1.0 * 2^127  *  1.0 * 2^-129 = +inf: ",
                   r4, FP_S_HUGE2)
 
/* ----------------------------------------------------------------------------
 * Test of single precision multiply: lf.mul.s
 * ------------------------------------------------------------------------- */
_mul_s:
        LOAD_STR (r3, "lf.mul.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer multiplication */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.mul.s  r4,r5,r6
        CHECK_RES (" 1.0 *  1.0 =  1.0: ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_THREE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.mul.s  r4,r5,r6
        CHECK_RES (" 3.0 *  1.0 =  3.0: ", r4, FP_S_THREE)
 
        /* Multiplication with fractions */
        LOAD_CONST (r5,FP_S_1_5)
        LOAD_CONST (r6,FP_S_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES (" 1.5 *  2.0 =  3.0: ", r4, FP_S_THREE)
 
        /* Multiplication with negative numbers */
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("-1.0 *  2.0 = -2.0: ", r4, FP_S_N_TWO)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("-1.0 * -2.0 = +2.0: ", r4, FP_S_TWO)
 
        /* Multiplication with zeros */
        LOAD_CONST (r5,FP_S_P_ZERO)
        LOAD_CONST (r6,FP_S_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("+0.0 *  2.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_N_ZERO)
        LOAD_CONST (r6,FP_S_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("+0.0 *  2.0 = +0.0: ", r4, FP_S_N_ZERO)
 
        /* Multiplication with infinities (more needed) */
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("+inf * -2.0 = -inf: ", r4, FP_S_N_INF)
 
        /* Multiplication with NaNs (more needed) */
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_TWO)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("+NaN *  2.0 = +NaN: ", r4, FP_S_P_NAN)
 
        /* Multiplication overflow */
        SET_RM  (FPCSR_RM_RIP)
 
        LOAD_CONST (r5,FP_S_HUGE1)
        LOAD_CONST (r6,FP_S_HUGE1)
        lf.mul.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127 *  1.0 * 2^127 = +inf: ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_N_HUGE1)
        LOAD_CONST (r6,FP_S_N_HUGE1)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^127 * -1.0 * 2^127 = +inf: ", r4, FP_S_P_INF)
 
        SET_RM  (FPCSR_RM_RIN)
        LOAD_CONST (r5,FP_S_N_HUGE1)
        LOAD_CONST (r6,FP_S_HUGE1)
        lf.mul.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^127 *  1.0 * 2^127 = -inf: ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_HUGE1)
        LOAD_CONST (r6,FP_S_N_HUGE1)
        lf.mul.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127 * -1.0 * 2^127 = -inf: ", r4, FP_S_N_INF)
 
 
/* ----------------------------------------------------------------------------
 * Test of single precision remainder: lf.rem.s
 * ------------------------------------------------------------------------- */
_rem_s:
        LOAD_STR (r3, "lf.rem.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer remainder */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 1.0 %  1.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 1.0 %  2.0 =  1.0: ", r4, FP_S_ONE)
 
        /* Remainder with fractions */
        // FIXME: This is failing, giving rem = -0.5 with softfloat
        /*
        LOAD_CONST (r5,FP_S_1_5)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 1.5 %  2.0 =  1.5: ", r4, FP_S_1_5)
        */
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_1_5)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 2.0 %  1.5 =  0.5: ", r4, FP_S_0_5)
 
        LOAD_CONST (r5,FP_S_THREE)
        LOAD_CONST (r6,FP_S_1_5)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 3.0 %  1.5 = +0.0: ", r4, FP_S_P_ZERO)
 
        /* Remainder with negative numbers */
        // FIXME: These next 4 are failing with the wrong signs on the results!
        /*
        LOAD_CONST (r5,FP_S_N_THREE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("-3.0 %  2.0 = -1.0: ", r4, FP_S_N_ONE)
 
        LOAD_CONST (r5,FP_S_N_THREE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("-3.0 %  2.0 = -1.0: ", r4, FP_S_N_ONE)
 
        LOAD_CONST (r5,FP_S_THREE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 3.0 % -2.0 =  1.0: ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_N_THREE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("-3.0 % -2.0 = -1.0: ", r4, FP_S_N_ONE)
        */
        /* Remainder with zeros (more are needed) */
        LOAD_CONST (r5,FP_S_P_ZERO)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("+0.0 %  2.0 = +0.0: ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_N_ZERO)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("-0.0 %  2.0 = -0.0: ", r4, FP_S_N_ZERO)
 
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 2.0 % +0.0 = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_N_TWO)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("-2.0 % +0.0 = -NaN: ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_N_ZERO)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 2.0 % -0.0 = -NaN: ", r4, FP_S_N_NAN)
 
        /* Remainder with infinities (more are needed) */
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 2.0 % +inf =  2.0: ", r4, FP_S_TWO)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("+inf %  2.0 = -NaN: ", r4, FP_S_N_NAN)
 
        /* Remainder with NaNs (more are needed) */
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 2.0 % +NaN = +NaN: ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_TWO)
        lf.rem.s  r4,r5,r6
        CHECK_RES ("+NaN %  2.0 = +NaN: ", r4, FP_S_P_NAN)
 
        /* Remainder with overflow of division (more are needed) */
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_SMALL1)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127  % 1.0 * 2^-129 = +0.0: ", r4, FP_S_P_ZERO)
 
        /* Remainder with underflow (more are needed) */
        LOAD_CONST (r5,FP_S_SMALL1)
        LOAD_CONST (r6,FP_S_HUGE2)
        lf.rem.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^-129 % 1.0 * 2^127  = +0.0: ", r4, FP_S_SMALL1)
 
        /* Remainder with denormalization (more are needed) */
 
/* ----------------------------------------------------------------------------
 * Test of single precision set flag if equal: lf.sfeq.s
 * ------------------------------------------------------------------------- */
_sfeq_s:
        LOAD_STR (r3, "lf.sfeq.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer equality */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 ==  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 ==  2.0: ", FALSE)
 
        /* Fractional equality */
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.5 ==  1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_0_5)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.5 ==  0.5: ", FALSE)
 
        /* Signed equality */
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("-1.5 == -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.5 == -1.5: ", FALSE)
 
        /* Equality of zeros */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("+0.0 == +0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("-0.0 == -0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("+0.0 == -0.0: ", TRUE)
 
        /* Equality with infinities (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 == +inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("+inf == +inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("-inf == -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("+inf == -inf: ", FALSE)
 
        /* Equality with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 == +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("+NaN == +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("-NaN == -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfeq.s  r4,r5
        CHECK_FLAG ("+NaN == -NaN: ", FALSE)
 
        /* Equality with denormalized numbers (more needed) */
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 == 1.0 * 2^-129: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 == 1.0 * 2^-128: ", FALSE)
 
        LOAD_CONST (r4,FP_S_HUGE1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfeq.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^126  == 1.0 * 2^-128: ", FALSE)
 
 
/* ----------------------------------------------------------------------------
 * Test of single precision set flag if greater than or equal: lf.sfge.s
 * ------------------------------------------------------------------------- */
_sfge_s:
        LOAD_STR (r3, "lf.sfge.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer greater than or equality */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 >=  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_TWO)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 2.0 >=  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 >=  2.0: ", FALSE)
 
        /* Fractional greater than or equality */
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.5 >=  1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_0_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.5 >=  0.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_0_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 0.5 >=  1.5: ", FALSE)
 
        /* Signed greater than or equality */
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-1.5 >= -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_0_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-1.5 >= -0.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_0_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-0.5 >= -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.5 >= -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-1.5 >=  1.5: ", FALSE)
 
        /* Greater than or equality of zeros */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+0.0 >= +0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-0.0 >= -0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+0.0 >= -0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-0.0 >= +0.0: ", TRUE)
 
        /* Greater than or equality with infinities (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 >= +inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+inf >=  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 >= -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-inf >=  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+inf >= +inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-inf >= -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+inf >= -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-inf >= +inf: ", FALSE)
 
        /* Greater than or equality with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 >= +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+NaN >= +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-NaN >= -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("+NaN >= -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfge.s  r4,r5
        CHECK_FLAG ("-NaN >= +NaN: ", FALSE)
 
        /* Greater than or equality with denormalized numbers (more needed) */
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 >= 1.0 * 2^-129: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 >= 1.0 * 2^-128: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 >= 1.0 * 2^-129: ", TRUE)
 
        LOAD_CONST (r4,FP_S_HUGE1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^126  >= 1.0 * 2^-128: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_HUGE1)
        lf.sfge.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 >= 1.0 * 2^126:  ", FALSE)
 
 
/* ----------------------------------------------------------------------------
 * Test of single precision set flag if greater than: lf.sfgt.s
 * ------------------------------------------------------------------------- */
_sfgt_s:
        LOAD_STR (r3, "lf.sfgt.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer greater than */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 >  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_TWO)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 2.0 >  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 >  2.0: ", FALSE)
 
        /* Fractional greater than */
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.5 >  1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_0_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.5 >  0.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_0_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 0.5 >  1.5: ", FALSE)
 
        /* Signed greater than */
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-1.5 > -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_0_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-1.5 > -0.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_0_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-0.5 > -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.5 > -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-1.5 >  1.5: ", FALSE)
 
        /* Greater than of zeros */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+0.0 > +0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-0.0 > -0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+0.0 > -0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-0.0 > +0.0: ", FALSE)
 
        /* Greater than with infinities (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 > +inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+inf >  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 > -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-inf >  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+inf > +inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-inf > -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+inf > -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-inf > +inf: ", FALSE)
 
        /* Greater than with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 > +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+NaN > +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-NaN > -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("+NaN > -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfgt.s  r4,r5
        CHECK_FLAG ("-NaN > +NaN: ", FALSE)
 
        /* Greater than with denormalized numbers (more needed) */
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 > 1.0 * 2^-129: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 > 1.0 * 2^-128: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 > 1.0 * 2^-129: ", TRUE)
 
        LOAD_CONST (r4,FP_S_HUGE1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^126  > 1.0 * 2^-128: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_HUGE1)
        lf.sfgt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 > 1.0 * 2^126:  ", FALSE)
 
/* ----------------------------------------------------------------------------
 * Test of single precision set flag if less than or equal: lf.sfle.s
 * ------------------------------------------------------------------------- */
_sfle_s:
        LOAD_STR (r3, "lf.sfle.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer less than or equality */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 <=  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_TWO)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 2.0 <=  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 <=  2.0: ", TRUE)
 
        /* Fractional less than or equality */
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.5 <=  1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_0_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.5 <=  0.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_0_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 0.5 <=  1.5: ", TRUE)
 
        /* Signed less than or equality */
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-1.5 <= -1.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_0_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-1.5 <= -0.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_0_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-0.5 <= -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.5 <= -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-1.5 <=  1.5: ", TRUE)
 
        /* Less than or equality of zeros */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+0.0 <= +0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-0.0 <= -0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+0.0 <= -0.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-0.0 <= +0.0: ", TRUE)
 
        /* Less than or equality with infinities (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 <= +inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+inf <=  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 <= -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-inf <=  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+inf <= +inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-inf <= -inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+inf <= -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-inf <= +inf: ", TRUE)
 
        /* Less than or equality with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 <= +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+NaN <= +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-NaN <= -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("+NaN <= -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfle.s  r4,r5
        CHECK_FLAG ("-NaN <= +NaN: ", FALSE)
 
        /* Less than or equality with denormalized numbers (more needed) */
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 <= 1.0 * 2^-129: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 <= 1.0 * 2^-128: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 <= 1.0 * 2^-129: ", FALSE)
 
        LOAD_CONST (r4,FP_S_HUGE1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^126  <= 1.0 * 2^-128: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_HUGE1)
        lf.sfle.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 <= 1.0 * 2^126:  ", TRUE)
 
 
/* ----------------------------------------------------------------------------
 * Test of single precision set flag if less than: lf.sflt.s
 * ------------------------------------------------------------------------- */
_sflt_s:
        LOAD_STR (r3, "lf.sflt.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer less than */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 <  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_TWO)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 2.0 <  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 <  2.0: ", TRUE)
 
        /* Fractional less than */
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.5 <  1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_0_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.5 <  0.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_0_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 0.5 <  1.5: ", TRUE)
 
        /* Signed less than */
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-1.5 < -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_0_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-1.5 < -0.5: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_0_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-0.5 < -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.5 < -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-1.5 <  1.5: ", TRUE)
 
        /* Less than of zeros */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+0.0 < +0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-0.0 < -0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+0.0 < -0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-0.0 < +0.0: ", FALSE)
 
        /* Less than with infinities (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 < +inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+inf <  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 < -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-inf <  1.0: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+inf < +inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-inf < -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+inf < -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-inf < +inf: ", TRUE)
 
        /* Less than with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 < +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+NaN < +NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-NaN < -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("+NaN < -NaN: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sflt.s  r4,r5
        CHECK_FLAG ("-NaN < +NaN: ", FALSE)
 
        /* Less than with denormalized numbers (more needed) */
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 < 1.0 * 2^-129: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 < 1.0 * 2^-128: ", TRUE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 < 1.0 * 2^-129: ", FALSE)
 
        LOAD_CONST (r4,FP_S_HUGE1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^126  < 1.0 * 2^-128: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL2)
        LOAD_CONST (r5,FP_S_HUGE1)
        lf.sflt.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-128 < 1.0 * 2^126:  ", TRUE)
 
/* ----------------------------------------------------------------------------
 * Test of single precision set flag if not equal: lf.sfne.s
 * ------------------------------------------------------------------------- */
_sfne_s:
        LOAD_STR (r3, "lf.sfne.s\n")
        l.jal   _puts
        l.nop
 
        /* Tests of integer inequality */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_ONE)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 !=  1.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_TWO)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 !=  2.0: ", TRUE)
 
        /* Fractional inequality */
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_1_5)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.5 !=  1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_0_5)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.5 !=  0.5: ", TRUE)
 
        /* Signed inequality */
        LOAD_CONST (r4,FP_S_N_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("-1.5 != -1.5: ", FALSE)
 
        LOAD_CONST (r4,FP_S_1_5)
        LOAD_CONST (r5,FP_S_N_1_5)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.5 != -1.5: ", TRUE)
 
        /* Inequality of zeros */
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_P_ZERO)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("+0.0 != +0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("-0.0 != -0.0: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_ZERO)
        LOAD_CONST (r5,FP_S_N_ZERO)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("+0.0 != -0.0: ", FALSE)
 
        /* Inequality with infinities (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 != +inf: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_P_INF)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("+inf != +inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_N_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("-inf != -inf: ", FALSE)
 
        LOAD_CONST (r4,FP_S_P_INF)
        LOAD_CONST (r5,FP_S_N_INF)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("+inf != -inf: ", TRUE)
 
        /* Inequality with NaNs (more needed) */
        LOAD_CONST (r4,FP_S_ONE)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 != +NaN: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_P_NAN)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("+NaN != +NaN: ", TRUE)
 
        LOAD_CONST (r4,FP_S_N_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("-NaN != -NaN: ", TRUE)
 
        LOAD_CONST (r4,FP_S_P_NAN)
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.sfne.s  r4,r5
        CHECK_FLAG ("+NaN != -NaN: ", TRUE)
 
        /* Inequality with denormalized numbers (more needed) */
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL1)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 != 1.0 * 2^-129: ", FALSE)
 
        LOAD_CONST (r4,FP_S_SMALL1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^-129 != 1.0 * 2^-128: ", TRUE)
 
        LOAD_CONST (r4,FP_S_HUGE1)
        LOAD_CONST (r5,FP_S_SMALL2)
        lf.sfne.s  r4,r5
        CHECK_FLAG (" 1.0 * 2^126  != 1.0 * 2^-128: ", TRUE)
 
/* ----------------------------------------------------------------------------
 * Test of single precision subtract: lf.sub.s
 * ------------------------------------------------------------------------- */
        .section .text
_sub_s:
        LOAD_STR (r3, "lf.sub.s\n")
        l.jal   _puts
        l.nop
 
        SET_RM  (FPCSR_RM_RIP)
 
        /* Simple integer subtraction */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_ZERO)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 -  0.0  =  1.0:  ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_ZERO)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - -0.0  =  1.0:  ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_ONE)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 -  1.0  = +0.0:  ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_ONE)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 2.0 -  1.0  =  1.0:  ", r4, FP_S_ONE)
 
        /* Fractional subtraction */
        LOAD_CONST (r5,FP_S_1_5)
        LOAD_CONST (r6,FP_S_1_5)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.5 -  1.5  = +0.0:  ", r4, FP_S_P_ZERO)
 
        LOAD_CONST (r5,FP_S_1_5)
        LOAD_CONST (r6,FP_S_0_5)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.5 -  0.5  =  1.0:  ", r4, FP_S_ONE)
 
        LOAD_CONST (r5,FP_S_1_5)
        LOAD_CONST (r6,FP_S_ONE)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.5 -  1.5  =  0.5:  ", r4, FP_S_0_5)
 
        /* Subtraction with negative numbers */
        LOAD_CONST (r5,FP_S_TWO)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 2.0 - -1.0  =  3.0:  ", r4, FP_S_THREE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_TWO)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - -2.0  =  3.0:  ", r4, FP_S_THREE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - -1.0  =  2.0:  ", r4, FP_S_TWO)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("-1.0 -  2.0  = -3.0:  ", r4, FP_S_N_THREE)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_TWO)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 -  2.0  = -1.0:  ", r4, FP_S_N_ONE)
 
        LOAD_CONST (r5,FP_S_N_ONE)
        LOAD_CONST (r6,FP_S_N_ONE)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("-1.0 - -1.0  =  0.0:  ", r4, FP_S_P_ZERO)
 
        /* Subtraction with infinities (more needed) */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - +inf  = -inf:  ", r4, FP_S_N_INF)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - -inf  = +inf:  ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_P_INF)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("+inf - +inf  = -NaN:  ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_INF)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("+inf - -inf  = +inf:  ", r4, FP_S_P_INF)
 
        LOAD_CONST (r5,FP_S_N_INF)
        LOAD_CONST (r6,FP_S_N_INF)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("-inf - -inf  = -NaN:  ", r4, FP_S_N_NAN)
 
        /* Subtraction with NaNs (more needed) */
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - +NaN  = +NaN:  ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - -NaN  = -NaN:  ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_P_NAN)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("+NaN - +NaN  = +NaN:  ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_P_NAN)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("+NaN - -NaN  = +NaN:  ", r4, FP_S_P_NAN)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        LOAD_CONST (r6,FP_S_N_NAN)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("-NaN - -NaN  = -NaN:  ", r4, FP_S_N_NAN)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_P_NAN_B)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - +sNaN = +qNaN: ", r4, 0x7fc00001)
 
        LOAD_CONST (r5,FP_S_ONE)
        LOAD_CONST (r6,FP_S_N_NAN_B)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 - -sNaN = -qNaN: ", r4, 0xffc00001)
 
        /* Subtraction with overflow (more neeeded) */
        SET_RM  (FPCSR_RM_RIN)
 
        LOAD_CONST (r5,FP_S_N_HUGE2)
        LOAD_CONST (r6,FP_S_HUGE2)
        lf.sub.s  r4,r5,r6
        CHECK_RES ("-1.0 * 2^127 -  1.0 * 2^127  = +inf:  ", r4, FP_S_N_INF)
 
        SET_RM  (FPCSR_RM_RIP)
        LOAD_CONST (r5,FP_S_HUGE2)
        LOAD_CONST (r6,FP_S_N_HUGE2)
        lf.sub.s  r4,r5,r6
        CHECK_RES (" 1.0 * 2^127 - -1.0 * 2^127  = -inf:  ", r4, FP_S_P_INF)
 
 
/* ----------------------------------------------------------------------------
 * All done
 * ------------------------------------------------------------------------- */
_exit:
        LOAD_STR (r3, "Test completed\n")
        l.jal   _puts
        l.nop
 
        l.movhi r3,hi(ALL_DONE)
        l.ori   r3,r3,lo(ALL_DONE)
        l.nop   NOP_REPORT              /* Should be 0xdeaddead */
 
        l.addi  r3,r0,0
        l.nop   NOP_EXIT
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[/] [openrisc/] [trunk/] [or1ksim/] [testsuite/] [test-code-or1k/] [fp/] [fp.S] - Blame information for rev 458

Line No.	Rev	Author	Line
1	104	jeremybenn	`/* fp.S. Floating point instruction set test of Or1ksim`
2
3			`Copyright (C) 1999-2006 OpenCores`
4			`Copyright (C) 2010 Embecosm Limited`
5	233	julius	`Copyright (C) 2010 ORSoC AB`
6	104	jeremybenn
7			`Contributors various OpenCores participants`
8			`Contributor Jeremy Bennett`
9	233	julius	`Contributor Julius Baxter`
10	104	jeremybenn
11			`This file is part of OpenRISC 1000 Architectural Simulator.`
12
13			`This program is free software; you can redistribute it and/or modify it`
14			`under the terms of the GNU General Public License as published by the Free`
15			`Software Foundation; either version 3 of the License, or (at your option)`
16			`any later version.`
17
18			`This program is distributed in the hope that it will be useful, but WITHOUT`
19			`ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or`
20			`FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for`
21			`more details.`
22
23			`You should have received a copy of the GNU General Public License along`
24			`with this program. If not, see . */`
25
26
27			`/* ----------------------------------------------------------------------------`
28			`* Test coverage`
29			`*`
30			`* At present the tests are only reasonably comprehensive for lf.add.s and`
31			`* lf.div.s. This is intended as a template for future work, and still has`
32			`* omissions even so.`
33			`*`
34			`* Basic tests are provided for all single precision floating point`
35			`* numbers. Since Or1ksim translates these operations into host FP, there is`
36			`* little point in testing more of the subtleties of IEEE 745.`
37			`*`
38			`* However in future this test could be used with OpenRISC hardware, in which`
39			`* case exhaustive testing would be essential.`
40			`* ------------------------------------------------------------------------- */`