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PseudoOps.txt
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PseudoOps.txt
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# Copyright (c) 2003-2010, Pete Sanderson and Kenneth Vollmar
#
# Developed by Pete Sanderson ([email protected])
# and Kenneth Vollmar ([email protected])
#
# Permission is hereby granted, free of charge, to any person obtaining
# a copy of this software and associated documentation files (the
# "Software"), to deal in the Software without restriction, including
# without limitation the rights to use, copy, modify, merge, publish,
# distribute, sublicense, and/or sell copies of the Software, and to
# permit persons to whom the Software is furnished to do so, subject
# to the following conditions:
#
# The above copyright notice and this permission notice shall be
# included in all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
# EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
# MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
# IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR
# ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF
# CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
# WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
#
# (MIT license, http://www.opensource.org/licenses/mit-license.html)
# File containing definitions of MIPS pseudo-ops
# File format:
# Each line contains specification for one pseudo-op, including optional description.
# First item is source statement syntax, specified in same "example" parser format used for regular instructions.
# Source statement specification ends with a tab. It is followed by a tab-separated list of basic instruction
# templates to complete and substitute for the pseudo-op.
# Format for specifying syntax of templates is different from specifying syntax of source statement:
# (n=0,1,2,3,...) is token position in source statement (operator is token 0, parentheses are tokens but commas aren't)
# RGn means substitute register found in n'th token of source statement
# NRn means substitute next higher register than the one in n'th token of source code
# OPn means substitute n'th token of source code as is
# LLn means substitute low order 16-bits from label address in source token n.
# LLnU means substitute low order 16-bits (unsigned) from label address in source token n.
# LLnPm (m=1,2,3,4) means substitute low order 16-bits from label address in source token n, after adding m.
# LHn means substitute high order 16-bits from label address in source token n. Must add 1 if address bit 15 is 1.
# LHnPm (m=1,2,3,4) means substitute high order 16-bits from label address in source token n, after adding m. Must then add 1 if bit 15 is 1.
# VLn means substitute low order 16-bits from 32-bit value in source token n.
# VLnU means substitute low order 16-bits (unsigned) from 32-bit value in source token n.
# VLnPm (m=1,2,3,4) means substitute low order 16-bits from 32-bit value in source token n, after adding m to value.
# VLnPmU (m=1,2,3,4) means substitute low order 16-bits(unsigned) from 32-bit value in source token n, after adding m to value.
# VHLn means substitute high order 16-bits from 32-bit value in source token n. Use this if later combined with low order 16-bits using "ori $1,$1,VLnU". See logical and branch operations.
# VHn means substitute high order 16-bits from 32-bit value in source token n, then add 1 if value's bit 15 is 1. Use this only if later instruction uses VLn($1) to calculate 32-bit address. See loads and stores.
# VHLnPm (m=1,2,3,4) means substitute high order 16-bits from 32-bit value in source token n, after adding m. See VHLn.
# VHnPm (m=1,2,3,4) means substitute high order 16-bits from 32-bit value in source token n, after adding m. Must then add 1 if bit 15 is 1. See VHn.
# LLP is similar to LLn, but is needed for "label+100000" address offset. Immediate is added before taking low order 16.
# LLPU is similar to LLn, but is needed for "label+100000" address offset. Immediate is added before taking low order 16 (unsigned).
# LLPPm (m=1,2,3,4) is similar to LLP except m is added along with immediate before taking low order 16.
# LHPA is similar to LHn, but is needed for "label+100000" address offset. Immediate is added before taking high order 16.
# LHPN is similar to LHPA, used only by "la" instruction. Address resolved by "ori" so do not add 1 if bit 15 is 1.
# LHPAPm (m=1,2,3,4) is similar to LHPA except value m is added along with immediate before taking high order 16.
# LHL means substitute high order 16-bits from label address in token 2 of "la" (load address) source statement.
# LAB means substitute textual label from last token of source statement. Used for various branches.
# S32 means substitute the result of subtracting the constant value in last token from 32. Used by "ror", "rol".
# DBNOP means Delayed Branching NOP - generate a "nop" instruction but only if delayed branching is enabled. Added in 3.4.1 release.
# BROFFnm means substitute n if delayed branching is NOT enabled otherwise substitute m. n and m are single digit numbers indicating constant branch offset (in words). Added in 3.4.1 release.
# COMPACT is a marker to separate the default template from a second template optimized for 16-bit addresses. See loads and stores having (data) label operands.
# Everything else is copied as is into the generated statement (you must use register numbers not mnemonics)
# The list of basic instruction templates is optionally followed a description of the instruction for help purposes.
# To add optional description, append a tab then the '#' character followed immediately (no spaces) by the description.
#
# See documentation for ExtendedInstruction.makeTemplateSubstitutions() for more details.
#
# Matching for a given instruction mnemonic is first-fit not best-fit. If an instruction has both 16 and 32-bit
# immediate operand options, they should be listed in that order (16-bit version first). Otherwise the 16-bit
# version will never be matched since the 32-bit version fits small immediate values first.
#
# The pseudo-op specification must start in the first column. If first column is blank, the line will be skipped!
#
# When specifying the example instruction (first item on line), the conventions I follow are:
# - for a register operand, specify a numbered register (e.g. $t1 or $f1) to represent any register in the set.
# The numerical value is not significant. This is NOT the case when writing the templates that follow!
# In the templates, numbered registers are parsed as is (use only $0 and $1, which are $zero and $at).
# - for an immediate operand, specify a positive value indicative of the expected range. I use 10 to represent
# a 5 bit value, 100 to represent a 16-bit value, and 100000 to represent a 32-bit value.
# - for a label operand, I use the string "label" (without the quotes).
# The idea is to give the parser an example that will be parsed into the desired token sequence. Syntax checking
# is done by comparing the source token sequence to list of token sequences generated from the examples.
# IMPORTANT NOTE: The use of $t1,$t2, etc in the instruction sample means that any CPU register reference
# can be used in that position. It is simply a placeholder. By contrast, when
# $1 is used in the template specification, $1 ($at) is literally placed into the generated
# instruction! If you want the generated code to echo the source register, use RG1,RG2, etc.
####################### arithmetic and branch pseudo-ops #####################
not $t1,$t2 nor RG1, RG2, $0 #Bitwise NOT (bit inversion)
# Here are some "convenience" arithmetic pseudo-ops. But do they encourage sloppy programming?
add $t1,$t2,-100 addi RG1, RG2, VL3 #ADDition : set $t1 to ($t2 plus 16-bit immediate)
add $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U add RG1, RG2, $1 #ADDition : set $t1 to ($t2 plus 32-bit immediate)
addu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U addu RG1, RG2, $1 #ADDition Unsigned : set $t1 to ($t2 plus 32-bit immediate), no overflow
addi $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U add RG1, RG2, $1 #ADDition Immediate : set $t1 to ($t2 plus 32-bit immediate)
addiu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U addu RG1, RG2, $1 #ADDition Immediate Unsigned: set $t1 to ($t2 plus 32-bit immediate), no overflow
sub $t1,$t2,-100 addi $1, $0, VL3 sub RG1, RG2, $1 #SUBtraction : set $t1 to ($t2 minus 16-bit immediate)
sub $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U sub RG1, RG2, $1 #SUBtraction : set $t1 to ($t2 minus 32-bit immediate)
subu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U subu RG1, RG2, $1 #SUBtraction Unsigned : set $t1 to ($t2 minus 32-bit immediate), no overflow
subi $t1,$t2,-100 addi $1, $0, VL3 sub RG1, RG2, $1 #SUBtraction Immediate : set $t1 to ($t2 minus 16-bit immediate)
subi $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U sub RG1, RG2, $1 #SUBtraction Immediate : set $t1 to ($t2 minus 32-bit immediate)
subiu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U subu RG1, RG2, $1 #SUBtraction Immediate Unsigned : set $t1 to ($t2 minus 32-bit immediate), no overflow
# feel free to add more convenience arithmetic pseduo-ops.
# convenience logical operations can be added too,
andi $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U and RG1, RG2, $1 #AND Immediate : set $t1 to ($t2 bitwise-AND 32-bit immediate)
ori $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U or RG1, RG2, $1 #OR Immediate : set $t1 to ($t2 bitwise-OR 32-bit immediate)
xori $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U xor RG1, RG2, $1 #XOR Immediate : set $t1 to ($t2 bitwise-exclusive-OR 32-bit immediate)
and $t1,$t2,100 andi RG1, RG2, VL3U #AND : set $t1 to ($t2 bitwise-AND 16-bit unsigned immediate)
or $t1,$t2,100 ori RG1, RG2, VL3U #OR : set $t1 to ($t2 bitwise-OR 16-bit unsigned immediate)
xor $t1,$t2,100 xori RG1, RG2, VL3U #XOR : set $t1 to ($t2 bitwise-exclusive-OR 16-bit unsigned immediate)
and $t1,100 andi RG1, RG1, VL2U #AND : set $t1 to ($t1 bitwise-AND 16-bit unsigned immediate)
or $t1,100 ori RG1, RG1, VL2U #OR : set $t1 to ($t1 bitwise-OR 16-bit unsigned immediate)
xor $t1,100 xori RG1, RG1, VL2U #XOR : set $t1 to ($t1 bitwise-exclusive-OR 16-bit unsigned immediate)
andi $t1,100 andi RG1, RG1, VL2U #AND Immediate : set $t1 to ($t1 bitwise-AND 16-bit unsigned immediate)
ori $t1,100 ori RG1, RG1, VL2U #OR Immediate : set $t1 to ($t1 bitwise-OR 16-bit unsigned immediate)
xori $t1,100 xori RG1, RG1, VL2U #XOR Immediate : set $t1 to ($t1 bitwise-exclusive-OR 16-bit unsigned immediate)
andi $t1,100000 lui $1, VHL2 ori $1, $1, VL2U and RG1, RG1, $1 #AND Immediate : set $t1 to ($t1 bitwise-AND 32-bit immediate)
ori $t1,100000 lui $1, VHL2 ori $1, $1, VL2U or RG1, RG1, $1 #OR Immediate : set $t1 to ($t1 bitwise-OR 32-bit immediate)
xori $t1,100000 lui $1, VHL2 ori $1, $1, VL2U xor RG1, RG1, $1 #XOR Immediate : set $t1 to ($t1 bitwise-exclusive-OR 32-bit immediate)
# Note: most of the expansions in this group were rewritten for Release 3.4.1 to remove internal branching.
seq $t1,$t2,$t3 subu RG1, RG2, RG3 ori $1, $0, 1 sltu RG1, RG1, $1 #Set EQual : if $t2 equal to $t3 then set $t1 to 1 else 0
seq $t1,$t2,-100 addi $1, $0, VL3 subu RG1, RG2, $1 ori $1, $0, 1 sltu RG1, RG1, $1 #Set EQual : if $t2 equal to 16-bit immediate then set $t1 to 1 else 0
seq $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U subu RG1, RG2, $1 ori $1, $0, 1 sltu RG1, RG1, $1 #Set EQual : if $t2 equal to 32-bit immediate then set $t1 to 1 else 0
sne $t1,$t2,$t3 subu RG1, RG2, RG3 sltu RG1, $0, RG1 #Set Not Equal : if $t2 not equal to $t3 then set $t1 to 1 else 0
sne $t1,$t2,-100 addi $1, $0, VL3 subu RG1, RG2, $1 sltu RG1, $0, RG1 #Set Not Equal : if $t2 not equal to 16-bit immediate then set $t1 to 1 else 0
sne $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U subu RG1, RG2, $1 sltu RG1, $0, RG1 #Set Not Equal : if $t2 not equal to 32-bit immediate then set $t1 to 1 else 0
sge $t1,$t2,$t3 slt RG1, RG2, RG3 ori $1, $0, 1 subu RG1, $1, RG1 #Set Greater or Equal : if $t2 greater or equal to $t3 then set $t1 to 1 else 0
sge $t1,$t2,-100 addi $1, $0, VL3 slt RG1, RG2, $1 ori $1, $0, 1 subu RG1, $1, RG1 #Set Greater or Equal : if $t2 greater or equal to 16-bit immediate then set $t1 to 1 else 0
sge $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U slt RG1, RG2, $1 ori $1, $0, 1 subu RG1, $1, RG1 #Set Greater or Equal : if $t2 greater or equal to 32-bit immediate then set $t1 to 1 else 0
sgeu $t1,$t2,$t3 sltu RG1, RG2, RG3 ori $1, $0, 1 subu RG1, $1, RG1 #Set Greater or Equal Unsigned : if $t2 greater or equal to $t3 (unsigned compare) then set $t1 to 1 else 0
sgeu $t1,$t2,-100 addi $1, $0, VL3 sltu RG1, RG2, $1 ori $1, $0, 1 subu RG1, $1, RG1 #Set Greater or Equal Unsigned : if $t2 greater or equal to 16-bit immediate (unsigned compare) then set $t1 to 1 else 0
sgeu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U sltu RG1, RG2, $1 ori $1, $0, 1 subu RG1, $1, RG1 #Set Greater or Equal Unsigned : if $t2 greater or equal to 32-bit immediate (unsigned compare) then set $t1 to 1 else 0
sgt $t1,$t2,$t3 slt RG1, RG3, RG2 #Set Greater Than : if $t2 greater than $t3 then set $t1 to 1 else 0
sgt $t1,$t2,-100 addi $1, $0, VL3 slt RG1, $1, RG2 #Set Greater Than : if $t2 greater than 16-bit immediate then set $t1 to 1 else 0
sgt $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U slt RG1, $1, RG2 #Set Greater Than : if $t2 greater than 32-bit immediate then set $t1 to 1 else 0
sgtu $t1,$t2,$t3 sltu RG1, RG3, RG2 #Set Greater Than Unsigned : if $t2 greater than $t3 (unsigned compare) then set $t1 to 1 else 0
sgtu $t1,$t2,-100 addi $1, $0, VL3 sltu RG1, $1, RG2 #Set Greater Than Unsigned : if $t2 greater than 16-bit immediate (unsigned compare) then set $t1 to 1 else 0
sgtu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U sltu RG1, $1, RG2 #Set Greater Than Unsigned : if $t2 greater than 32-bit immediate (unsigned compare) then set $t1 to 1 else 0
sle $t1,$t2,$t3 slt RG1, RG3, RG2 ori $1, $0, 1 subu RG1, $1, RG1 #Set Less or Equal : if $t2 less or equal to $t3 then set $t1 to 1 else 0
sle $t1,$t2,-100 addi $1, $0, VL3 slt RG1, $1, RG2 ori $1, $0, 1 subu RG1, $1, RG1 #Set Less or Equal : if $t2 less or equal to 16-bit immediate then set $t1 to 1 else 0
sle $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U slt RG1, $1, RG2 ori $1, $0, 1 subu RG1, $1, RG1 #Set Less or Equal : if $t2 less or equal to 32-bit immediate then set $t1 to 1 else 0
sleu $t1,$t2,$t3 sltu RG1, RG3, RG2 ori $1, $0, 1 subu RG1, $1, RG1 #Set Less or Equal Unsigned: if $t2 less or equal to $t3 (unsigned compare) then set $t1 to 1 else 0
sleu $t1,$t2,-100 addi $1, $0, VL3 sltu RG1, $1, RG2 ori $1, $0, 1 subu RG1, $1, RG1 #Set Less or Equal Unsigned: if $t2 less or equal to 16-bit immediate (unsigned compare) then set $t1 to 1 else 0
sleu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U sltu RG1, $1, RG2 ori $1, $0, 1 subu RG1, $1, RG1 #Set Less or Equal Unsigned: if $t2 less or equal to 32-bit immediate (unsigned compare) then set $t1 to 1 else 0
move $t1,$t2 addu RG1, $0, RG2 #MOVE : Set $t1 to contents of $t2
abs $t1,$t2 sra $1, RG2, 31 xor RG1, $1, RG2 subu RG1, RG1, $1 #ABSolute value : Set $t1 to absolute value of $t2 (algorithm from Hacker's Delight)
neg $t1,$t2 sub RG1, $0, RG2 #NEGate : Set $t1 to negation of $t2
negu $t1,$t2 subu RG1, $0, RG2 #NEGate Unsigned : Set $t1 to negation of $t2, no overflow
b label bgez $0, LAB #Branch : Branch to statement at label unconditionally
beqz $t1,label beq RG1, $0, LAB #Branch if EQual Zero : Branch to statement at label if $t1 is equal to zero
bnez $t1,label bne RG1, $0, LAB #Branch if Not Equal Zero : Branch to statement at label if $t1 is not equal to zero
beq $t1,-100,label addi $1, $0, VL2 beq $1, RG1, LAB #Branch if EQual : Branch to statement at label if $t1 is equal to 16-bit immediate
beq $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U beq $1, RG1, LAB #Branch if EQual : Branch to statement at label if $t1 is equal to 32-bit immediate
bne $t1,-100,label addi $1, $0, VL2 bne $1, RG1, LAB #Branch if Not Equal : Branch to statement at label if $t1 is not equal to 16-bit immediate
bne $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U bne $1, RG1, LAB #Branch if Not Equal : Branch to statement at label if $t1 is not equal to 32-bit immediate
bge $t1,$t2,label slt $1, RG1, RG2 beq $1, $0, LAB #Branch if Greater or Equal : Branch to statement at label if $t1 is greater or equal to $t2
bge $t1,-100,label slti $1, RG1, VL2 beq $1, $0, LAB #Branch if Greater or Equal : Branch to statement at label if $t1 is greater or equal to 16-bit immediate
bge $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U slt $1, RG1, $1 beq $1, $0, LAB #Branch if Greater or Equal : Branch to statement at label if $t1 is greater or equal to 32-bit immediate
bgeu $t1,$t2,label sltu $1, RG1, RG2 beq $1, $0, LAB #Branch if Greater or Equal Unsigned : Branch to statement at label if $t1 is greater or equal to $t2 (unsigned compare)
bgeu $t1,-100,label sltiu $1, RG1, VL2 beq $1, $0, LAB #Branch if Greater or Equal Unsigned : Branch to statement at label if $t1 is greater or equal to 16-bit immediate (unsigned compare)
bgeu $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U sltu $1, RG1, $1 beq $1, $0, LAB #Branch if Greater or Equal Unsigned : Branch to statement at label if $t1 is greater or equal to 32-bit immediate (unsigned compare)
bgt $t1,$t2,label slt $1, RG2, RG1 bne $1, $0, LAB #Branch if Greater Than : Branch to statement at label if $t1 is greater than $t2
bgt $t1,-100,label addi $1, $0, VL2 slt $1, $1, RG1 bne $1, $0, LAB #Branch if Greater Than : Branch to statement at label if $t1 is greater than 16-bit immediate
bgt $t1,100000,label lui $1, VHL2P1 ori $1, $1, VL2P1U slt $1, RG1, $1 beq $1, $0, LAB #Branch if Greater Than : Branch to statement at label if $t1 is greater than 32-bit immediate
bgtu $t1,$t2,label sltu $1, RG2, RG1 bne $1, $0, LAB #Branch if Greater Than Unsigned: Branch to statement at label if $t1 is greater than $t2 (unsigned compare)
bgtu $t1,-100,label addi $1, $0, VL2 sltu $1, $1, RG1 bne $1, $0, LAB #Branch if Greater Than Unsigned: Branch to statement at label if $t1 is greater than 16-bit immediate (unsigned compare)
bgtu $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U sltu $1, $1, RG1 bne $1, $0, LAB #Branch if Greater Than Unsigned: Branch to statement at label if $t1 is greater than 16-bit immediate (unsigned compare)
ble $t1,$t2,label slt $1, RG2, RG1 beq $1, $0, LAB #Branch if Less or Equal : Branch to statement at label if $t1 is less than or equal to $t2
ble $t1,-100,label addi $1, RG1, -1 slti $1, $1, VL2 bne $1, $0, LAB #Branch if Less or Equal : Branch to statement at label if $t1 is less than or equal to 16-bit immediate
ble $t1,100000,label lui $1, VHL2P1 ori $1, $1, VL2P1U slt $1, RG1, $1 bne $1, $0, LAB #Branch if Less or Equal : Branch to statement at label if $t1 is less than or equal to 32-bit immediate
bleu $t1,$t2,label sltu $1, RG2, RG1 beq $1, $0, LAB #Branch if Less or Equal Unsigned : Branch to statement at label if $t1 is less than or equal to $t2 (unsigned compare)
bleu $t1,-100,label addi $1, $0, VL2 sltu $1, $1, RG1 beq $1, $0, LAB #Branch if Less or Equal Unsigned : Branch to statement at label if $t1 is less than or equal to 16-bit immediate (unsigned compare)
bleu $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U sltu $1, $1, RG1 beq $1, $0, LAB #Branch if Less or Equal Unsigned : Branch to statement at label if $t1 is less than or equal to 32-bit immediate (unsigned compare)
blt $t1,$t2,label slt $1, RG1, RG2 bne $1, $0, LAB #Branch if Less Than : Branch to statement at label if $t1 is less than $t2
blt $t1,-100,label slti $1, RG1, VL2 bne $1, $0, LAB #Branch if Less Than : Branch to statement at label if $t1 is less than 16-bit immediate
blt $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U slt $1, RG1, $1 bne $1, $0, LAB #Branch if Less Than : Branch to statement at label if $t1 is less than 32-bit immediate
bltu $t1,$t2,label sltu $1, RG1, RG2 bne $1, $0, LAB #Branch if Less Than Unsigned : Branch to statement at label if $t1 is less than $t2
bltu $t1,-100,label sltiu $1, RG1, VL2 bne $1, $0, LAB #Branch if Less Than Unsigned : Branch to statement at label if $t1 is less than 16-bit immediate
bltu $t1,100000,label lui $1, VHL2 ori $1, $1, VL2U sltu $1, RG1, $1 bne $1, $0, LAB #Branch if Less Than Unsigned : Branch to statement at label if $t1 is less than 32-bit immediate
rol $t1,$t2,$t3 subu $1, $0, RG3 srlv $1, RG2, $1 sllv RG1, RG2, RG3 or RG1, RG1, $1 #ROtate Left : Set $t1 to ($t2 rotated left by number of bit positions specified in $t3)
rol $t1,$t2,10 srl $1, RG2, S32 sll RG1, RG2, OP3 or RG1, RG1, $1 #ROtate Left : Set $t1 to ($t2 rotated left by number of bit positions specified in 5-bit immediate)
ror $t1,$t2,$t3 subu $1, $0, RG3 sllv $1, RG2, $1 srlv RG1, RG2, RG3 or RG1, RG1, $1 #ROtate Right : Set $t1 to ($t2 rotated right by number of bit positions specified in $t3)
ror $t1,$t2,10 sll $1, RG2, S32 srl RG1, RG2, OP3 or RG1, RG1, $1 #ROtate Right : Set $t1 to ($t2 rotated right by number of bit positions specified in 5-bit immediate)
mfc1.d $t1,$f2 mfc1 RG1, RG2 mfc1 NR1, NR2 #Move From Coprocessor 1 Double : Set $t1 to contents of $f2, set next higher register from $t1 to contents of next higher register from $f2
mtc1.d $t1,$f2 mtc1 RG1, RG2 mtc1 NR1, NR2 #Move To Coprocessor 1 Double : Set $f2 to contents of $t1, set next higher register from $f2 to contents of next higher register from $t1
mul $t1,$t2,-100 addi $1, $0, VL3 mul RG1, RG2, $1 #MULtiplication : Set HI to high-order 32 bits, LO and $t1 to low-order 32 bits of the product of $t2 and 16-bit signed immediate (use mfhi to access HI, mflo to access LO)
mul $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U mul RG1, RG2, $1 #MULtiplication : Set HI to high-order 32 bits, LO and $t1 to low-order 32 bits of the product of $t2 and 32-bit immediate (use mfhi to access HI, mflo to access LO)
mulu $t1,$t2,$t3 multu RG2, RG3 mflo RG1 #MULtiplication Unsigned : Set HI to high-order 32 bits, LO and $t1 to low-order 32 bits of ($t2 multiplied by $t3, unsigned multiplication)
mulu $t1,$t2,-100 addi $1, $0, VL3 multu RG2, $1 mflo RG1 #MULtiplication Unsigned : Set HI to high-order 32 bits, LO and $t1 to low-order 32 bits of ($t2 multiplied by 16-bit immediate, unsigned multiplication)
mulu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U multu RG2, $1 mflo RG1 #MULtiplication Unsigned : Set HI to high-order 32 bits, LO and $t1 to low-order 32 bits of ($t2 multiplied by 32-bit immediate, unsigned multiplication)
mulo $t1,$t2,$t3 mult RG2, RG3 mfhi $1 mflo RG1 sra RG1, RG1, 31 beq $1, RG1, BROFF12 DBNOP break mflo RG1 #MULtiplication with Overflow : Set $t1 to low-order 32 bits of the product of $t2 and $t3
mulo $t1,$t2,-100 addi $1, $0, VL3 mult RG2, $1 mfhi $1 mflo RG1 sra RG1, RG1, 31 beq $1, RG1, BROFF12 DBNOP break mflo RG1 #MULtiplication with Overflow : Set $t1 to low-order 32 bits of the product of $t2 and signed 16-bit immediate
mulo $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U mult RG2, $1 mfhi $1 mflo RG1 sra RG1, RG1, 31 beq $1, RG1, BROFF12 DBNOP break mflo RG1 #MULtiplication with Overflow : Set $t1 to low-order 32 bits of the product of $t2 and 32-bit immediate
mulou $t1,$t2,$t3 multu RG2, RG3 mfhi $1 beq $1,$0, BROFF12 DBNOP break mflo RG1 #MULtiplication with Overflow Unsigned : Set $t1 to low-order 32 bits of the product of $t2 and $t3
mulou $t1,$t2,-100 addi $1, $0, VL3 multu RG2, $1 mfhi $1 beq $1,$0, BROFF12 DBNOP break mflo RG1 #MULtiplication with Overflow Unsigned : Set $t1 to low-order 32 bits of the product of $t2 and signed 16-bit immediate
mulou $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U multu RG2, $1 mfhi $1 beq $1,$0, BROFF12 DBNOP break mflo RG1 #MULtiplication with Overflow Unsigned : Set $t1 to low-order 32 bits of the product of $t2 and 32-bit immediate
div $t1,$t2,$t3 bne RG3, $0, BROFF12 DBNOP break div RG2, RG3 mflo RG1 #DIVision : Set $t1 to ($t2 divided by $t3, integer division)
div $t1,$t2,-100 addi $1, $0, VL3 div RG2, $1 mflo RG1 #DIVision : Set $t1 to ($t2 divided by 16-bit immediate, integer division)
div $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U div RG2, $1 mflo RG1 #DIVision : Set $t1 to ($t2 divided by 32-bit immediate, integer division)
divu $t1,$t2,$t3 bne RG3, $0, BROFF12 DBNOP break divu RG2, RG3 mflo RG1 #DIVision Unsigned : Set $t1 to ($t2 divided by $t3, unsigned integer division)
divu $t1,$t2,-100 addi $1, $0, VL3 divu RG2, $1 mflo RG1 #DIVision Unsigned : Set $t1 to ($t2 divided by 16-bit immediate, unsigned integer division)
divu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U divu RG2, $1 mflo RG1 #DIVision Unsigned : Set $t1 to ($t2 divided by 32-bit immediate, unsigned integer division)
rem $t1,$t2,$t3 bne RG3, $0, BROFF12 DBNOP break div RG2, RG3 mfhi RG1 #REMainder : Set $t1 to (remainder of $t2 divided by $t3)
rem $t1,$t2,-100 addi $1, $0, VL3 div RG2, $1 mfhi RG1 #REMainder : Set $t1 to (remainder of $t2 divided by 16-bit immediate)
rem $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U div RG2, $1 mfhi RG1 #REMainder : Set $t1 to (remainder of $t2 divided by 32-bit immediate)
remu $t1,$t2,$t3 bne RG3, $0, BROFF12 DBNOP break divu RG2, RG3 mfhi RG1 #REMainder : Set $t1 to (remainder of $t2 divided by $t3, unsigned division)
remu $t1,$t2,-100 addi $1, $0, VL3 divu RG2, $1 mfhi RG1 #REMainder : Set $t1 to (remainder of $t2 divided by 16-bit immediate, unsigned division)
remu $t1,$t2,100000 lui $1, VHL3 ori $1, $1, VL3U divu RG2, $1 mfhi RG1 #REMainder : Set $t1 to (remainder of $t2 divided by 32-bit immediate, unsigned division)
######################### load/store pseudo-ops start here ##########################
#
# Most of these simply provide a variety of convenient memory addressing modes for
# specifying load/store address.
#
li $t1,-100 addiu RG1, $0, VL2 #Load Immediate : Set $t1 to 16-bit immediate (sign-extended)
li $t1,100 ori RG1, $0, VL2U #Load Immediate : Set $t1 to unsigned 16-bit immediate (zero-extended)
li $t1,100000 lui $1, VHL2 ori RG1, $1, VL2U #Load Immediate : Set $t1 to 32-bit immediate
la $t1,($t2) addi RG1, RG3, 0 #Load Address : Set $t1 to contents of $t2
la $t1,-100 addiu RG1, $0, VL2 #Load Address : Set $t1 to 16-bit immediate (sign-extended)
la $t1,100 ori RG1, $0, VL2U #Load Address : Set $t1 to 16-bit immediate (zero-extended)
la $t1,100000 lui $1, VHL2 ori RG1, $1, VL2U #Load Address : Set $t1 to 32-bit immediate
la $t1,100($t2) ori $1, $0, VL2U add RG1, RG4, $1 #Load Address : Set $t1 to sum (of $t2 and 16-bit immediate)
la $t1,100000($t2) lui $1, VHL2 ori $1, $1, VL2U add RG1, RG4, $1 #Load Address : Set $t1 to sum (of $t2 and 32-bit immediate)
la $t1,label lui $1, LHL ori RG1, $1, LL2U COMPACT addi RG1, $0, LL2 #Load Address : Set $t1 to label's address
la $t1,label($t2) lui $1, LHL ori $1, $1, LL2U add RG1, RG4, $1 COMPACT addi RG1, RG4, LL2 #Load Address : Set $t1 to sum (of $t2 and label's address)
la $t1,label+100000 lui $1, LHPN ori RG1, $1, LLPU #Load Address : Set $t1 to sum (of label's address and 32-bit immediate)
la $t1,label+100000($t2) lui $1, LHPN ori $1, $1, LLPU add RG1, RG6, $1 #Load Address : Set $t1 to sum (of label's address, 32-bit immediate, and $t2)
lw $t1,($t2) lw RG1,0(RG3) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,-100 lw RG1, VL2($0) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,100 ori $1, $0, VL2U lw RG1, 0($1) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,100000 lui $1, VH2 lw RG1,VL2($1) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lw RG1, 0($1) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lw RG1, VL2($1) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,label lui $1, LH2 lw RG1, LL2($1) COMPACT lw RG1, LL2($0) #Load Word : Set $t1 to contents of memory word at label's address
lw $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lw RG1, LL2($1) COMPACT lw RG1, LL2(RG4) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,label+100000 lui $1, LHPA lw RG1, LLP($1) #Load Word : Set $t1 to contents of effective memory word address
lw $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lw RG1, LLP($1) #Load Word : Set $t1 to contents of effective memory word address
sw $t1,($t2) sw RG1,0(RG3) #Store Word : Store $t1 contents into effective memory word address
sw $t1,-100 sw RG1, VL2($0) #Store Word : Store $t1 contents into effective memory word address
sw $t1,100 ori $1, $0, VL2U sw RG1, 0($1) #Store Word : Store $t1 contents into effective memory word address
sw $t1,100000 lui $1, VH2 sw RG1,VL2($1) #Store Word : Store $t1 contents into effective memory word address
sw $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 sw RG1, 0($1) #Store Word : Store $t1 contents into effective memory word address
sw $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 sw RG1, VL2($1) #Store Word : Store $t1 contents into effective memory word address
sw $t1,label lui $1, LH2 sw RG1, LL2($1) COMPACT sw RG1, LL2($0) #Store Word : Store $t1 contents into memory word at label's address
sw $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 sw RG1, LL2($1) COMPACT sw RG1, LL2(RG4) #Store Word : Store $t1 contents into effective memory word address
sw $t1,label+100000 lui $1, LHPA sw RG1, LLP($1) #Store Word : Store $t1 contents into effective memory word address
sw $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sw RG1, LLP($1) #Store Word : Store $t1 contents into effective memory word address
lh $t1,($t2) lh RG1,0(RG3) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,-100 lh RG1, VL2($0) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,100 ori $1, $0, VL2U lh RG1, 0($1) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,100000 lui $1, VH2 lh RG1,VL2($1) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lh RG1, 0($1) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lh RG1, VL2($1) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,label lui $1, LH2 lh RG1, LL2($1) COMPACT lh RG1, LL2($0) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lh RG1, LL2($1) COMPACT lh RG1, LL2(RG4) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,label+100000 lui $1, LHPA lh RG1, LLP($1) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
lh $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lh RG1, LLP($1) #Load Halfword : Set $t1 to sign-extended 16-bit value from effective memory halfword address
sh $t1,($t2) sh RG1,0(RG3) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,-100 sh RG1, VL2($0) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,100 ori $1, $0, VL2U sh RG1, 0($1) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,100000 lui $1, VH2 sh RG1,VL2($1) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 sh RG1, 0($1) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 sh RG1, VL2($1) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,label lui $1, LH2 sh RG1, LL2($1) COMPACT sh RG1, LL2($0) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 sh RG1, LL2($1) COMPACT sh RG1, LL2(RG4) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,label+100000 lui $1, LHPA sh RG1, LLP($1) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
sh $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sh RG1, LLP($1) #Store Halfword : Store the low-order 16 bits of $t1 into the effective memory halfword address
lb $t1,($t2) lb RG1,0(RG3) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,-100 lb RG1, VL2($0) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,100 ori $1, $0, VL2U lb RG1, 0($1) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,100000 lui $1, VH2 lb RG1,VL2($1) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lb RG1, 0($1) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lb RG1, VL2($1) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,label lui $1, LH2 lb RG1, LL2($1) COMPACT lb RG1, LL2($0) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lb RG1, LL2($1) COMPACT lb RG1, LL2(RG4) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,label+100000 lui $1, LHPA lb RG1, LLP($1) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
lb $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lb RG1, LLP($1) #Load Byte : Set $t1 to sign-extended 8-bit value from effective memory byte address
sb $t1,($t2) sb RG1,0(RG3) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,-100 sb RG1, VL2($0) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,100 ori $1, $0, VL2U sb RG1, 0($1) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,100000 lui $1, VH2 sb RG1,VL2($1) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 sb RG1, 0($1) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 sb RG1, VL2($1) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,label lui $1, LH2 sb RG1, LL2($1) COMPACT sb RG1, LL2($0) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 sb RG1, LL2($1) COMPACT sb RG1, LL2(RG4) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,label+100000 lui $1, LHPA sb RG1, LLP($1) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
sb $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sb RG1, LLP($1) #Store Byte : Store the low-order 8 bits of $t1 into the effective memory byte address
lhu $t1,($t2) lhu RG1,0(RG3) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,-100 lhu RG1,VL2($0) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,100 ori $1, $0, VL2U lhu RG1, 0($1) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,100000 lui $1, VH2 lhu RG1,VL2($1) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lhu RG1, 0($1) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lhu RG1, VL2($1) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,label lui $1, LH2 lhu RG1, LL2($1) COMPACT lhu RG1, LL2($0) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lhu RG1, LL2($1) COMPACT lhu RG1, LL2(RG4) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,label+100000 lui $1, LHPA lhu RG1, LLP($1) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lhu $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lhu RG1, LLP($1) #Load Halfword Unsigned : Set $t1 to zero-extended 16-bit value from effective memory halfword address
lbu $t1,($t2) lbu RG1,0(RG3) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,-100 lbu RG1,VL2($0) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,100 ori $1, $0, VL2U lbu RG1, 0($1) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,100000 lui $1, VH2 lbu RG1,VL2($1) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lbu RG1, 0($1) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lbu RG1, VL2($1) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,label lui $1, LH2 lbu RG1, LL2($1) COMPACT lbu RG1, LL2($0) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lbu RG1, LL2($1) COMPACT lbu RG1, LL2(RG4) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,label+100000 lui $1, LHPA lbu RG1, LLP($1) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lbu $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lbu RG1, LLP($1) #Load Byte Unsigned : Set $t1 to zero-extended 8-bit value from effective memory byte address
lwl $t1,($t2) lwl RG1,0(RG3) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,-100 lwl RG1,VL2($0) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,100 ori $1, $0, VL2U lwl RG1, 0($1) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,100000 lui $1, VH2 lwl RG1,VL2($1) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lwl RG1, 0($1) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lwl RG1, VL2($1) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,label lui $1, LH2 lwl RG1, LL2($1) COMPACT lwl RG1, LL2($0) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lwl RG1, LL2($1) COMPACT lwl RG1, LL2(RG4) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,label+100000 lui $1, LHPA lwl RG1, LLP($1) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
lwl $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lwl RG1, LLP($1) #Load Word Left : Load from 1 to 4 bytes left-justified into $t1, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,($t2) swl RG1,0(RG3) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,-100 swl RG1,VL2($0) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,100 ori $1, $0, VL2U swl RG1, 0($1) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,100000 lui $1, VH2 swl RG1,VL2($1) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 swl RG1, 0($1) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 swl RG1, VL2($1) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,label lui $1, LH2 swl RG1, LL2($1) COMPACT swl RG1, LL2($0) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 swl RG1, LL2($1) COMPACT swl RG1, LL2(RG4) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,label+100000 lui $1, LHPA swl RG1, LLP($1) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
swl $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 swl RG1, LLP($1) #Store Word Left : Store high-order 1 to 4 bytes of $t1 into memory, starting with effective memory byte address and continuing through the low-order byte of its word
lwr $t1,($t2) lwr RG1,0(RG3) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,-100 lwr RG1,VL2($0) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,100 ori $1, $0, VL2U lwr RG1, 0($1) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,100000 lui $1, VH2 lwr RG1,VL2($1) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 lwr RG1, 0($1) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lwr RG1, VL2($1) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,label lui $1, LH2 lwr RG1, LL2($1) COMPACT lwr RG1, LL2($0) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lwr RG1, LL2($1) COMPACT lwr RG1, LL2(RG4) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,label+100000 lui $1, LHPA lwr RG1, LLP($1) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
lwr $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lwr RG1, LLP($1) #Load Word Right : Load from 1 to 4 bytes right-justified into $t1, starting with effective memory byte address and continuing through the high-order byte of its word
swr $t1,($t2) swr RG1,0(RG3) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,-100 swr RG1,VL2($0) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,100 ori $1, $0, VL2U swr RG1, 0 #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,100000 lui $1, VH2 swr RG1,VL2($1) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 swr RG1, 0($1) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 swr RG1, VL2($1) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,label lui $1, LH2 swr RG1, LL2($1) COMPACT swr RG1, LL2($0) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 swr RG1, LL2($1) COMPACT swr RG1, LL2(RG4) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,label+100000 lui $1, LHPA swr RG1, LLP($1) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
swr $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 swr RG1, LLP($1) #Store Word Right : Store low-order 1 to 4 bytes of $t1 into memory, starting with high-order byte of word containing effective memory byte address and continuing through that byte address
ll $t1,($t2) ll RG1,0(RG3) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,-100 ll RG1,VL2($0) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,100 ori $1, $0, VL2U ll RG1, 0($1) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,100000 lui $1, VH2 ll RG1,VL2($1) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 ll RG1, 0($1) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 ll RG1, VL2($1) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,label lui $1, LH2 ll RG1, LL2($1) COMPACT ll RG1, LL2($0) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 ll RG1, LL2($1) COMPACT ll RG1, LL2(RG4) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,label+100000 lui $1, LHPA ll RG1, LLP($1) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
ll $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 ll RG1, LLP($1) #Load Linked : Paired with Store Conditional (sc) to perform atomic read-modify-write. Treated as equivalent to Load Word (lw) because MARS does not simulate multiple processors.
sc $t1,($t2) sc RG1,0(RG3) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,-100 sc RG1,VL2($0) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,100 ori $1, $0, VL2U sc RG1, 0($1) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,100000 lui $1, VH2 sc RG1,VL2($1) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,100($t2) ori $1, $0, VL2U addu $1, $1, RG4 sc RG1, 0($1) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 sc RG1, VL2($1) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,label lui $1, LH2 sc RG1, LL2($1) COMPACT sc RG1, LL2($0) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 sc RG1, LL2($1) COMPACT sc RG1, LL2(RG4) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,label+100000 lui $1, LHPA sc RG1, LLP($1) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
sc $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sc RG1, LLP($1) #Store Conditional : Paired with Load Linked (ll) to perform atomic read-modify-write. Treated as equivalent to Store Word (sw) because MARS does not simulate multiple processors.
# Unaligned and double loads and stores. All the them require assembler to add a constant
# byte offset (from 1 to 4 bytes) to the given or calculated address.
# NOTE: I have abandoned the "accepted" expansion of immed16($reg) addressing form for the
# unaligned and double load/store pseudo-instructions because they produce what I consider
# incorrect results for immediate values at the upper edge of the signed 16-bit range
# (32765 through 32767). The expansion of these pseudo's requires adding an additional
# byte offset (from 1 to 4 bytes) to the immediate value, which overflows the signed 16
# bit range and results in a large negative offset with no counterbalancing increment
# to the high order 16-bits. Thus if the two pieces of unaligned data end up in different
# words, they are stored 64K bytes apart! For example, the normal expansion of
# "usw $8,32767($9)" would be "swl $8,-32766($9)", "swr $8, 32767($9)" Both SPIM and
# Britten's text do this but I consider it incorrect. My compromise is the following:
# since each of the expansion calls for two calculated offsets, one of which can possibly
# overflow due to the addition but the other will not (because there is no addition),
# I'll code the expansion to treat the at-risk calculated offset as 32-bits (it will generate
# the lui and addu, which is unnecessary in almost every case but is always correct)
# and the second as 16-bits. I'll group all instructions for this addressing mode together.
# ulw $t1,-100($t2) lwl RG1, VL2P3(RG4) lwr RG1, VL2(RG4) -- used by SPIM but not me.
# usw $t1,-100($t2) swl RG1, VL2P3(RG4) swr RG1, VL2(RG4) -- used by SPIM but not me.
ulw $t1,-100($t2) lui $1, VH2P3 addu $1, $1, RG4 lwl RG1, VL2P3($1) lwr RG1, VL2(RG4) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulh $t1,-100($t2) lui $1, VH2P1 addu $1, $1, RG4 lb RG1, VL2P1($1) lbu $1, VL2(RG4) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulhu $t1,-100($t2) lui $1, VH2P1 addu $1, $1, RG4 lbu RG1, VL2P1($1) lbu $1, VL2(RG4) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ld $t1,-100($t2) lw RG1, VL2(RG4) lui $1, VH2P4 addu $1, $1, RG4 lw NR1, VL2P4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory byte address
usw $t1,-100($t2) lui $1, VH2P3 addu $1, $1, RG4 swl RG1, VL2P3($1) swr RG1, VL2(RG4) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
ush $t1,-100($t2) sb RG1, VL2(RG4) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, VH2P1 addu $1, $1, RG4 sb RG1, VL2P1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
sd $t1,-100($t2) sw RG1, VL2(RG4) lui $1, VH2P4 addu $1, $1, RG4 sw NR1, VL2P4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory byte address
# here are the remaining addressing modes, grouped by instruction.
ulw $t1,100000 lui $1, VH2P3 lwl RG1, VL2P3($1) lui $1, VH2 lwr RG1, VL2($1) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulw $t1,label lui $1, LH2P3 lwl RG1, LL2P3($1) lui $1, LH2 lwr RG1, LL2($1) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulw $t1,label+100000 lui $1, LHPAP3 lwl RG1, LLPP3($1) lui $1, LHPA lwr RG1, LLP($1) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulw $t1,($t2) lwl RG1, 3(RG3) lwr RG1, 0(RG3) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulw $t1,100000($t2) lui $1, VH2P3 addu $1, $1, RG4 lwl RG1, VL2P3($1) lui $1, VH2 addu $1, $1, RG4 lwr RG1, VL2($1) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulw $t1,label($t2) lui $1, LH2P3 addu $1, $1, RG4 lwl RG1, LL2P3($1) lui $1, LH2 addu $1, $1, RG4 lwr RG1, LL2($1) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulw $t1,label+100000($t2) lui $1, LHPAP3 addu $1, $1, RG6 lwl RG1, LLPP3($1) lui $1, LHPA addu $1, $1, RG6 lwr RG1, LLP($1) #Unaligned Load Word : Set $t1 to the 32 bits starting at effective memory byte address
ulh $t1,100000 lui $1, VH2P1 lb RG1, VL2P1($1) lui $1, VH2 lbu $1, VL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulh $t1,label lui $1, LH2P1 lb RG1, LL2P1($1) lui $1, LH2 lbu $1, LL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulh $t1,label+100000 lui $1, LHPAP1 lb RG1, LLPP1($1) lui $1, LHPA lbu $1, LLP($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulh $t1,($t2) lb RG1, 1(RG3) lbu $1, 0(RG3) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulh $t1,100000($t2) lui $1, VH2P1 addu $1, $1, RG4 lb RG1, VL2P1($1) lui $1, VH2 addu $1, $1, RG4 lbu $1, VL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulh $t1,label($t2) lui $1, LH2P1 addu $1, $1, RG4 lb RG1, LL2P1($1) lui $1, LH2 addu $1, $1, RG4 lbu $1, LL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulh $t1,label+100000($t2) lui $1, LHPAP1 addu $1, $1, RG6 lb RG1, LLPP1($1) lui $1, LHPA addu $1, $1, RG6 lbu $1, LLP($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, sign-extended, starting at effective memory byte address
ulhu $t1,100000 lui $1, VH2P1 lbu RG1, VL2P1($1) lui $1, VH2 lbu $1, VL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ulhu $t1,label lui $1, LH2P1 lbu RG1, LL2P1($1) lui $1, LH2 lbu $1, LL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ulhu $t1,label+100000 lui $1, LHPAP1 lbu RG1, LLPP1($1) lui $1, LHPA lbu $1, LLP($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ulhu $t1,($t2) lbu RG1, 1(RG3) lbu $1, 0(RG3) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ulhu $t1,100000($t2) lui $1, VH2P1 addu $1, $1, RG4 lbu RG1, VL2P1($1) lui $1, VH2 addu $1, $1, RG4 lbu $1, VL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ulhu $t1,label($t2) lui $1, LH2P1 addu $1, $1, RG4 lbu RG1, LL2P1($1) lui $1, LH2 addu $1, $1, RG4 lbu $1, LL2($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ulhu $t1,label+100000($t2) lui $1, LHPAP1 addu $1, $1, RG6 lbu RG1, LLPP1($1) lui $1, LHPA addu $1, $1, RG6 lbu $1, LLP($1) sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Load Halfword : Set $t1 to the 16 bits, zero-extended, starting at effective memory byte address
ld $t1,100000 lui $1, VH2 lw RG1, VL2($1) lui $1, VH2P4 lw NR1, VL2P4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
ld $t1,label lui $1, LH2 lw RG1, LL2($1) lui $1, LH2P4 lw NR1, LL2P4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
ld $t1,label+100000 lui $1, LHPA lw RG1, LLP($1) lui $1, LHPAP4 lw NR1, LLPP4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
ld $t1,($t2) lw RG1, 0(RG3) lw NR1, 4(RG3) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
ld $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lw RG1, VL2($1) lui $1, VH2P4 addu $1, $1, RG4 lw NR1, VL2P4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
ld $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 lw RG1, LL2($1) lui $1, LH2P4 addu $1, $1, RG4 lw NR1, LL2P4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
ld $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lw RG1, LLP($1) lui $1, LHPAP4 addu $1, $1, RG6 lw NR1, LLPP4($1) #Load Doubleword : Set $t1 and the next register to the 64 bits starting at effective memory word address
usw $t1,100000 lui $1, VH2P3 swl RG1, VL2P3($1) lui $1, VH2 swr RG1, VL2($1) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
usw $t1,label lui $1, LH2P3 swl RG1, LL2P3($1) lui $1, LH2 swr RG1, LL2($1) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
usw $t1,label+100000 lui $1, LHPAP3 swl RG1, LLPP3($1) lui $1, LHPA swr RG1, LLP($1) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
usw $t1,($t2) swl RG1, 3(RG3) swr RG1, 0(RG3) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
usw $t1,100000($t2) lui $1, VH2P3 addu $1, $1, RG4 swl RG1, VL2P3($1) lui $1, VH2 addu $1, $1, RG4 swr RG1, VL2($1) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
usw $t1,label($t2) lui $1, LH2P3 addu $1, $1, RG4 swl RG1, LL2P3($1) lui $1, LH2 addu $1, $1, RG4 swr RG1, LL2($1) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
usw $t1,label+100000($t2) lui $1, LHPAP3 addu $1, $1, RG6 swl RG1, LLPP3($1) lui $1, LHPA addu $1, $1, RG6 swr RG1, LLP($1) #Unaligned Store Word : Store $t1 contents into the 32 bits starting at effective memory byte address
ush $t1,100000 lui $1, VH2 sb RG1, VL2($1) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, VH2P1 sb RG1, VL2P1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
ush $t1,label lui $1, LH2 sb RG1, LL2($1) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, LH2P1 sb RG1, LL2P1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
ush $t1,label+100000 lui $1, LHPA sb RG1, LLP($1) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, LHPAP1 sb RG1, LLPP1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
ush $t1,($t2) sb RG1, 0(RG3) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 sb RG1, 1(RG3) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
ush $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 sb RG1, VL2($1) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, VH2P1 addu $1, $1, RG4 sb RG1, VL2P1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
ush $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 sb RG1, LL2($1) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, LH2P1 addu $1, $1, RG4 sb RG1, LL2P1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
ush $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sb RG1, LLP($1) sll $1, RG1, 24 srl RG1, RG1, 8 or RG1, RG1, $1 lui $1, LHPAP1 addu $1, $1, RG6 sb RG1, LLPP1($1) srl $1, RG1, 24 sll RG1, RG1, 8 or RG1, RG1, $1 #Unaligned Store Halfword: Store low-order halfword $t1 contents into the 16 bits starting at effective memory byte address
sd $t1,100000 lui $1, VH2 sw RG1, VL2($1) lui $1, VH2P4 sw NR1, VL2P4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
sd $t1,label lui $1, LH2 sw RG1, LL2($1) lui $1, LH2P4 sw NR1, LL2P4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
sd $t1,label+100000 lui $1, LHPA sw RG1, LLP($1) lui $1, LHPAP4 sw NR1, LLPP4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
sd $t1,($t2) sw RG1, 0(RG3) sw NR1, 4(RG3) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
sd $t1,100000($t2) lui $1, VH2 addu $1, $1, RG4 sw RG1, VL2($1) lui $1, VH2P4 addu $1, $1, RG4 sw NR1, VL2P4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
sd $t1,label($t2) lui $1, LH2 addu $1, $1, RG4 sw RG1, LL2($1) lui $1, LH2P4 addu $1, $1, RG4 sw NR1, LL2P4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
sd $t1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sw RG1, LLP($1) lui $1, LHPAP4 addu $1, $1, RG6 sw NR1, LLPP4($1) #Store Doubleword : Store contents of $t1 and the next register to the 64 bits starting at effective memory word address
# load and store pseudo-instructions for floating point (coprocessor 1) registers
lwc1 $f1,($t2) lwc1 RG1,0(RG3) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,-100 lwc1 RG1,VL2($0) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,100000 lui $1, VH2 lwc1 RG1,VL2($1) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lwc1 RG1, VL2($1) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,label lui $1, LH2 lwc1 RG1, LL2($1) COMPACT lwc1 RG1, LL2($0) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,label($t2) lui $1, LH2 addu $1, $1, RG4 lwc1 RG1, LL2($1) COMPACT lwc1 RG1, LL2(RG4) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,label+100000 lui $1, LHPA lwc1 RG1, LLP($1) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
lwc1 $f1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lwc1 RG1, LLP($1) #Load Word Coprocessor 1 : Set $f1 to 32-bit value from effective memory word address
ldc1 $f2,($t2) ldc1 RG1,0(RG3) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,-100 ldc1 RG1,VL2($0) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,100000 lui $1, VH2 ldc1 RG1,VL2($1) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,100000($t2) lui $1, VH2 addu $1, $1, RG4 ldc1 RG1, VL2($1) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,label lui $1, LH2 ldc1 RG1, LL2($1) COMPACT ldc1 RG1, LL2($0) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,label($t2) lui $1, LH2 addu $1, $1, RG4 ldc1 RG1, LL2($1) COMPACT ldc1 RG1, LL2(RG4) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,label+100000 lui $1, LHPA ldc1 RG1, LLP($1) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
ldc1 $f2,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 ldc1 RG1, LLP($1) #Load Doubleword Coprocessor 1 : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
swc1 $f1,($t2) swc1 RG1,0(RG3) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,-100 swc1 RG1,VL2($0) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,100000 lui $1, VH2 swc1 RG1,VL2($1) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,100000($t2) lui $1, VH2 addu $1, $1, RG4 swc1 RG1, VL2($1) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,label lui $1, LH2 swc1 RG1, LL2($1) COMPACT swc1 RG1, LL2($0) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,label($t2) lui $1, LH2 addu $1, $1, RG4 swc1 RG1, LL2($1) COMPACT swc1 RG1, LL2(RG4) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,label+100000 lui $1, LHPA swc1 RG1, LLP($1) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
swc1 $f1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 swc1 RG1, LLP($1) #Store Word Coprocessor 1 : Store 32-bit value from $f1 to effective memory word address
sdc1 $f2,($t2) sdc1 RG1,0(RG3) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,-100 sdc1 RG1,VL2($0) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,100000 lui $1, VH2 sdc1 RG1,VL2($1) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,100000($t2) lui $1, VH2 addu $1, $1, RG4 sdc1 RG1, VL2($1) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,label lui $1, LH2 sdc1 RG1, LL2($1) COMPACT sdc1 RG1, LL2($0) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,label($t2) lui $1, LH2 addu $1, $1, RG4 sdc1 RG1, LL2($1) COMPACT sdc1 RG1, LL2(RG4) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,label+100000 lui $1, LHPA sdc1 RG1, LLP($1) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
sdc1 $f2,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sdc1 RG1, LLP($1) #Store Doubleword Coprocessor 1 : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
l.s $f1,($t2) lwc1 RG1,0(RG3) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,-100 lwc1 RG1,VL2($0) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,100000 lui $1, VH2 lwc1 RG1,VL2($1) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,100000($t2) lui $1, VH2 addu $1, $1, RG4 lwc1 RG1, VL2($1) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,label lui $1, LH2 lwc1 RG1, LL2($1) COMPACT lwc1 RG1, LL2($0) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,label($t2) lui $1, LH2 addu $1, $1, RG4 lwc1 RG1, LL2($1) COMPACT lwc1 RG1, LL2(RG4) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,label+100000 lui $1, LHPA lwc1 RG1, LLP($1) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
l.s $f1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 lwc1 RG1, LLP($1) #Load floating point Single precision : Set $f1 to 32-bit value at effective memory word address
s.s $f1,($t2) swc1 RG1,0(RG3) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,-100 swc1 RG1,VL2($0) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,100000 lui $1, VH2 swc1 RG1,VL2($1) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,100000($t2) lui $1, VH2 addu $1, $1, RG4 swc1 RG1, VL2($1) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,label lui $1, LH2 swc1 RG1, LL2($1) COMPACT swc1 RG1, LL2($0) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,label($t2) lui $1, LH2 addu $1, $1, RG4 swc1 RG1, LL2($1) COMPACT swc1 RG1, LL2(RG4) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,label+100000 lui $1, LHPA swc1 RG1, LLP($1) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
s.s $f1,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 swc1 RG1, LLP($1) #Store floating point Single precision : Store 32-bit value from $f1 to effective memory word address
l.d $f2,($t2) ldc1 RG1,0(RG3) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,-100 ldc1 RG1,VL2($0) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,100000 lui $1, VH2 ldc1 RG1,VL2($1) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,100000($t2) lui $1, VH2 addu $1, $1, RG4 ldc1 RG1, VL2($1) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,label lui $1, LH2 ldc1 RG1, LL2($1) COMPACT ldc1 RG1, LL2($0) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,label($t2) lui $1, LH2 addu $1, $1, RG4 ldc1 RG1, LL2($1) COMPACT ldc1 RG1, LL2(RG4) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,label+100000 lui $1, LHPA ldc1 RG1, LLP($1) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
l.d $f2,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 ldc1 RG1, LLP($1) #Load floating point Double precision : Set $f2 and $f3 register pair to 64-bit value at effective memory doubleword address
s.d $f2,($t2) sdc1 RG1,0(RG3) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,-100 sdc1 RG1,VL2($0) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,100000 lui $1, VH2 sdc1 RG1,VL2($1) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,100000($t2) lui $1, VH2 addu $1, $1, RG4 sdc1 RG1, VL2($1) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,label lui $1, LH2 sdc1 RG1, LL2($1) COMPACT sdc1 RG1, LL2($0) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,label($t2) lui $1, LH2 addu $1, $1, RG4 sdc1 RG1, LL2($1) COMPACT sdc1 RG1, LL2(RG4) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,label+100000 lui $1, LHPA sdc1 RG1, LLP($1) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address
s.d $f2,label+100000($t2) lui $1, LHPA addu $1, $1, RG6 sdc1 RG1, LLP($1) #Store floating point Double precision : Store 64 bits from $f2 and $f3 register pair to effective memory doubleword address