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/* fp.S. Floating point instruction set test of Or1ksim
 
   Copyright (C) 1999-2006 OpenCores
   Copyright (C) 2010 Embecosm Limited
 
   Contributors various OpenCores participants
   Contributor Jeremy Bennett 
 
   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
 *
 * 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
 
#define MC_CSR          (0x00)
#define MC_POC          (0x04)
#define MC_BA_MASK      (0x08)
#define MC_CSC(i)       (0x10 + (i) * 8)
#define MC_TMS(i)       (0x14 + (i) * 8)
 
/* ----------------------------------------------------------------------------
 * 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:
 
/* ----------------------------------------------------------------------------
 * 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"
        l.addi    r1,r0,0
 
        .section .text
        .org 0x100
_reset:
        l.movhi r1,hi(_stack)           /* Set up the stack */
        l.ori   r1,r1,lo(_stack)
 
        l.movhi r3,hi(_init_mc)         /* Code starts with MC setup */
        l.ori   r3,r3,lo(_init_mc)
        l.jr    r3
        l.nop
 
/* ----------------------------------------------------------------------------
 * 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
 
/* ----------------------------------------------------------------------------
 * Memory controller initialization initialization
 * ------------------------------------------------------------------------- */
_init_mc:
 
        l.movhi r3,hi(MC_BASE_ADDR)
        l.ori   r3,r3,lo(MC_BASE_ADDR)
 
        l.addi  r4,r3,MC_CSC(0)
        l.movhi r5,hi(FLASH_BASE_ADDR)
        l.srai  r5,r5,6
        l.ori   r5,r5,0x0025
        l.sw    0(r4),r5
 
        l.addi  r4,r3,MC_TMS(0)
        l.movhi r5,hi(FLASH_TMS_VAL)
        l.ori   r5,r5,lo(FLASH_TMS_VAL)
        l.sw    0(r4),r5
 
        l.addi  r4,r3,MC_BA_MASK
        l.addi  r5,r0,MC_MASK_VAL
        l.sw    0(r4),r5
 
        l.addi  r4,r3,MC_CSR
        l.movhi r5,hi(MC_CSR_VAL)
        l.ori   r5,r5,lo(MC_CSR_VAL)
        l.sw    0(r4),r5
 
        l.addi  r4,r3,MC_TMS(1)
        l.movhi r5,hi(SDRAM_TMS_VAL)
        l.ori   r5,r5,lo(SDRAM_TMS_VAL)
        l.sw    0(r4),r5
 
        l.addi  r4,r3,MC_CSC(1)
        l.movhi r5,hi(SDRAM_BASE_ADDR)
        l.srai  r5,r5,6
        l.ori   r5,r5,0x0411
        l.sw    0(r4),r5
 
/* ----------------------------------------------------------------------------
 * Test of single precision add: lf.add.s
 * ------------------------------------------------------------------------- */
        .section .text
_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_P_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) */
        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, 0x80000000)
 
        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, 0x80000000)
 
        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, 0x80000000)
 
        LOAD_CONST (r5,FP_S_N_NAN)
        lf.ftoi.s  r4,r5
        CHECK_RES ("(int) -NaN          = -2^31: ", r4, 0x80000000)
 
/* ----------------------------------------------------------------------------
 * 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) */
        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)
 
        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 */
        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_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)
 
        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)
 
/* ----------------------------------------------------------------------------
 * 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 */
        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 */
        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
 
        /* 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) */
        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)
 
        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 104

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
6			`Contributors various OpenCores participants`
7			`Contributor Jeremy Bennett`
8
9			`This file is part of OpenRISC 1000 Architectural Simulator.`
10
11			`This program is free software; you can redistribute it and/or modify it`
12			`under the terms of the GNU General Public License as published by the Free`
13			`Software Foundation; either version 3 of the License, or (at your option)`
14			`any later version.`
15
16			`This program is distributed in the hope that it will be useful, but WITHOUT`
17			`ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or`
18			`FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for`
19			`more details.`
20
21			`You should have received a copy of the GNU General Public License along`
22			`with this program. If not, see . */`
23
24
25			`/* ----------------------------------------------------------------------------`
26			`* Test coverage`
27			`*`
28			`* At present the tests are only reasonably comprehensive for lf.add.s and`
29			`* lf.div.s. This is intended as a template for future work, and still has`
30			`* omissions even so.`
31			`*`
32			`* Basic tests are provided for all single precision floating point`
33			`* numbers. Since Or1ksim translates these operations into host FP, there is`
34			`* little point in testing more of the subtleties of IEEE 745.`
35			`*`
36			`* However in future this test could be used with OpenRISC hardware, in which`
37			`* case exhaustive testing would be essential.`
38			`* ------------------------------------------------------------------------- */`
39
40