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1 6 hellwig
 
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Instruction Formats
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-------------------
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RRR (three register operands)
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RRS (two registers and a signed half operand)
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RRH (two registers and an unsigned half operand)
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RHH (one register and a half operand, high-order 16 bits encoded)
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RRB (two registers and a 16 bit signed offset operand)
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J   (no registers and a 26 bit signed offset operand)
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JR  (one register operand)
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13
 
14
Instruction Set
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---------------
16
 
17
Notation:
18
  'r[n]'        The bits representing 'r' are padded with zeroes
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                to the left (or zeroes are dropped from the left)
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                until a width of n bits is reached.
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  'a || b'      The bits representing 'a' and 'b' are concatenated;
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                'a' occupies the more significant bits.
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All numbers are given in decimal (base 10), except when prefixed
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with "0x", which means they are given in hexadecimal (base 16).
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26
ADD (add)
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  format:       RRR
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  coding:       0x00[6] || rs1[5] || rs2[5] || rd[5] || 0[11]
29
  assembler:    add  rd,rs1,rs2
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  example:      add  $1,$2,$3
31
  operation:    The contents of register rs2 are added to the contents
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                of register rs1. The result is stored into register rd.
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                Overflow is ignored.
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35
ADDI (add immediate)
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  format:       RRS
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  coding:       0x01[6] || rs1[5] || rd[5] || simm[16]
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  assembler:    add  rd,rs1,simm
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  example:      add  $1,$2,1234
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  operation:    The sign-extended immediate constant simm is added to
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                the contents of register rs1. The result is stored into
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                register rd. Overflow is ignored.
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44
SUB (subtract)
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  format:       RRR
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  coding:       0x02[6] || rs1[5] || rs2[5] || rd[5] || 0[11]
47
  assembler:    sub  rd,rs1,rs2
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  example:      sub  $1,$2,$3
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  operation:    The contents of register rs2 are subtracted from the
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                contents of register rs1. The result is stored into
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                register rd. Overflow is ignored.
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53
SUBI (subtract immediate)
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  format:       RRS
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  coding:       0x03[6] || rs1[5] || rd[5] || simm[16]
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  assembler:    sub  rd,rs1,simm
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  example:      add  $1,$2,1234
58
  operation:    The sign-extended immediate constant simm is subtracted
59
                from the contents of register rs1. The result is stored
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                into register rd. Overflow is ignored.
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62
AND (logical and)
63
  format:       RRR
64
  coding:       0x10[6] || rs1[5] || rs2[5] || rd[5] || 0[11]
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  assembler:    and  rd,rs1,rs2
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  example:      and  $1,$2,$3
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  operation:    The contents of register rs2 are bitwise anded with the
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                contents of register rs1. The result is stored into
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                register rd.
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71
ANDI (logical and immediate)
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  format:       RRH
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  coding:       0x11[6] || rs1[5] || rd[5] || uimm[16]
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  assembler:    and  rd,rs1,uimm
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  example:      and  $1,$2,1234
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  operation:    The zero-extended immediate constant uimm is bitwise
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                anded with the contents of register rs1. The result
78
                is stored into register rd.
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80
OR (logical or)
81
  format:       RRR
82
  coding:       0x12[6] || rs1[5] || rs2[5] || rd[5] || 0[11]
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  assembler:    or  rd,rs1,rs2
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  example:      or  $1,$2,$3
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  operation:    The contents of register rs2 are bitwise ored with the
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                contents of register rs1. The result is stored into
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                register rd.
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89
ORI (logical or immediate)
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  format:       RRH
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  coding:       0x13[6] || rs1[5] || rd[5] || uimm[16]
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  assembler:    or  rd,rs1,uimm
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  example:      or  $1,$2,1234
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  operation:    The zero-extended immediate constant uimm is bitwise
95
                ored with the contents of register rs1. The result
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                is stored into register rd.
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98
XOR (logical xor)
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  format:       RRR
100
  coding:       0x14[6] || rs1[5] || rs2[5] || rd[5] || 0[11]
101
  assembler:    xor  rd,rs1,rs2
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  example:      xor  $1,$2,$3
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  operation:    The contents of register rs2 are bitwise xored with the
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                contents of register rs1. The result is stored into
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                register rd.
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                Remark: (a xor b) <=> ((a and ~b) or (~a and b))
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108
XORI (logical xor immediate)
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  format:       RRH
110
  coding:       0x15[6] || rs1[5] || rd[5] || uimm[16]
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  assembler:    xor  rd,rs1,uimm
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  example:      xor  $1,$2,1234
113
  operation:    The zero-extended immediate constant uimm is bitwise
114
                xored with the contents of register rs1. The result
115
                is stored into register rd.
116
                Remark: (a xor b) <=> ((a and ~b) or (~a and b))
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118
XNOR (logical xnor)
119
  format:       RRR
120
  coding:       0x16[6] || rs1[5] || rs2[5] || rd[5] || 0[11]
121
  assembler:    xnor  rd,rs1,rs2
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  example:      xnor  $1,$2,$3
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  operation:    The contents of register rs2 are bitwise xnored with the
124
                contents of register rs1. The result is stored into
125
                register rd.
126
                Remark: (a xnor b) <=> ((a and b) or (~a and ~b))
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128
XNORI (logical xnor immediate)
129
  format:       RRH
130
  coding:       0x17[6] || rs1[5] || rd[5] || uimm[16]
131
  assembler:    xnor  rd,rs1,uimm
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  example:      xnor  $1,$2,1234
133
  operation:    The zero-extended immediate constant uimm is bitwise
134
                xnored with the contents of register rs1. The result
135
                is stored into register rd.
136
                Remark: (a xnor b) <=> ((a and b) or (~a and ~b))
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138
LDHI (load high immediate)
139
  format:       RHH
140
  coding:       0x1F[6] || 0[5] || rd[5] || uimm[16]
141
  assembler:    ldhi  rd,uimm
142
  example:      ldhi  $1,1234
143
  operation:    The zero-extended immediate constant uimm is shifted
144
                left by 16 bits. The result is stored into register rd.
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146
BEQ (branch on equal)
147
  format:       RRB
148
  coding:       0x20[6] || rs1[5] || rs2[5] || simm[16]
149
  assembler:    beq  rs1,rs2,target
150
  example:      beq  $1,$2,label3
151
  operation:    If the contents of register rs1 are equal to the contents
152
                of register rs2, the sign-extended immediate constant
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                simm is shifted left by two bits and added to the address
154
                of the instruction following the branch instruction. The
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                result is placed into the program counter. If the contents
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                differ, the next instruction after the branch is executed.
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158
BNE (branch on not equal)
159
  format:       RRB
160
  coding:       0x21[6] || rs1[5] || rs2[5] || simm[16]
161
  assembler:    bne  rs1,rs2,target
162
  example:      bne  $1,$2,label3
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  operation:    If the contents of register rs1 are not equal to the contents
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                of register rs2, the sign-extended immediate constant
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                simm is shifted left by two bits and added to the address
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                of the instruction following the branch instruction. The
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                result is placed into the program counter. If the contents
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                are equal, the next instruction after the branch is executed.
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170
BLEU (branch on less or equal unsigned)
171
  format:       RRB
172
  coding:       0x23[6] || rs1[5] || rs2[5] || simm[16]
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  assembler:    bleu  rs1,rs2,target
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  example:      bleu  $1,$2,label3
175
  operation:    If the contents of register rs1 are less than or equal
176
                to the contents of register rs2 (both are interpreted as
177
                unsigned numbers), the sign-extended immediate constant
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                simm is shifted left by two bits and added to the address
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                of the instruction following the branch instruction. The
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                result is placed into the program counter. If the contents
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                do not satisfy the condition, the next instruction after
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                the branch is executed.
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184
BLTU (branch on less than unsigned)
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  format:       RRB
186
  coding:       0x25[6] || rs1[5] || rs2[5] || simm[16]
187
  assembler:    bltu  rs1,rs2,target
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  example:      bltu  $1,$2,label3
189
  operation:    If the contents of register rs1 are less than the contents
190
                of register rs2 (both are interpreted as unsigned numbers),
191
                the sign-extended immediate constant simm is shifted left
192
                by two bits and added to the address of the instruction
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                following the branch instruction. The result is placed into
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                the program counter. If the contents do not satisfy the
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                condition, the next instruction after the branch is executed.
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BGEU (branch on greater or equal unsigned)
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  format:       RRB
199
  coding:       0x27[6] || rs1[5] || rs2[5] || simm[16]
200
  assembler:    bgeu  rs1,rs2,target
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  example:      bgeu  $1,$2,label3
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  operation:    If the contents of register rs1 are greater than or equal
203
                to the contents of register rs2 (both are interpreted as
204
                unsigned numbers), the sign-extended immediate constant
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                simm is shifted left by two bits and added to the address
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                of the instruction following the branch instruction. The
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                result is placed into the program counter. If the contents
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                do not satisfy the condition, the next instruction after
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                the branch is executed.
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211
BGTU (branch on greater than unsigned)
212
  format:       RRB
213
  coding:       0x29[6] || rs1[5] || rs2[5] || simm[16]
214
  assembler:    bgtu  rs1,rs2,target
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  example:      bgtu  $1,$2,label3
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  operation:    If the contents of register rs1 are greater than the contents
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                of register rs2 (both are interpreted as unsigned numbers),
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                the sign-extended immediate constant simm is shifted left
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                by two bits and added to the address of the instruction
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                following the branch instruction. The result is placed into
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                the program counter. If the contents do not satisfy the
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                condition, the next instruction after the branch is executed.
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J (jump)
225
  format:       J
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  coding:       0x2A[6] || simm[26]
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  assembler:    j  target
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  example:      j  label3
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  operation:    The sign-extended immediate constant simm is shifted left
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                by two bits and added to the address of the instruction
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                following the jump instruction. The result is placed into
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                the program counter.
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JR (jump register)
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  format:       JR
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  coding:       0x2B[6] || rs[5] || 0[5] || 0[16]
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  assembler:    jr  rs
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  example:      jr  $31
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  operation:    The contents of register rs are placed into the program
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                counter.
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JAL (jump and link)
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  format:       J
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  coding:       0x2C[6] || simm[26]
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  assembler:    jal  target
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  example:      jal  label3
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  operation:    The address of the instruction following the jal instruction
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                is placed into register 31. The sign-extended immediate
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                constant simm is shifted left by two bits and added to the
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                address of the instruction following the jal instruction.
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                The result is placed into the program counter.
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LDW (load word)
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  format:       RRS
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  coding:       0x30[6] || rs[5] || rd[5] || simm[16]
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  assembler:    ldw  rd,rs,simm
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  example:      ldw  $1,$2,1234
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  operation:    The sign-extended immediate constant simm is added to the
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                contents of register rs to form an effective memory address.
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                A word is read from this address and stored into register
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                rd.
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LDH (load halfword)
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  format:       RRS
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  coding:       0x31[6] || rs[5] || rd[5] || simm[16]
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  assembler:    ldh  rd,rs,simm
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  example:      ldh  $1,$2,1234
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  operation:    The sign-extended immediate constant simm is added to the
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                contents of register rs to form an effective memory address.
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                A halfword is read from this address, sign-extended, and
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                stored into register rd.
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LDHU (load halfword unsigned)
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  format:       RRS
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  coding:       0x32[6] || rs[5] || rd[5] || simm[16]
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  assembler:    ldhu  rd,rs,simm
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  example:      ldhu  $1,$2,1234
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  operation:    The sign-extended immediate constant simm is added to the
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                contents of register rs to form an effective memory address.
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                A halfword is read from this address, zero-extended, and
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                stored into register rd.
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LDB (load byte)
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  format:       RRS
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  coding:       0x33[6] || rs[5] || rd[5] || simm[16]
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  assembler:    ldb  rd,rs,simm
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  example:      ldb  $1,$2,1234
288
  operation:    The sign-extended immediate constant simm is added to the
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                contents of register rs to form an effective memory address.
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                A byte is read from this address, sign-extended, and stored
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                into register rd.
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LDBU (load byte unsigned)
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  format:       RRS
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  coding:       0x34[6] || rs[5] || rd[5] || simm[16]
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  assembler:    ldbu  rd,rs,simm
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  example:      ldbu  $1,$2,1234
298
  operation:    The sign-extended immediate constant simm is added to the
299
                contents of register rs to form an effective memory address.
300
                A byte is read from this address, zero-extended, and stored
301
                into register rd.
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303
STW (store word)
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  format:       RRS
305
  coding:       0x35[6] || rs[5] || rd[5] || simm[16]
306
  assembler:    stw  rd,rs,simm
307
  example:      stw  $1,$2,1234
308
  operation:    The sign-extended immediate constant simm is added to the
309
                contents of register rs to form an effective memory address.
310
                The contents of register rd (all 32 bits) are stored
311
                as a word to this address.
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313
STH (store halfword)
314
  format:       RRS
315
  coding:       0x36[6] || rs[5] || rd[5] || simm[16]
316
  assembler:    sth  rd,rs,simm
317
  example:      sth  $1,$2,1234
318
  operation:    The sign-extended immediate constant simm is added to the
319
                contents of register rs to form an effective memory address.
320
                The contents of register rd (the lower 16 bits) are stored
321
                as a halfword to this address.
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323
STB (store byte)
324
  format:       RRS
325
  coding:       0x37[6] || rs[5] || rd[5] || simm[16]
326
  assembler:    stb  rd,rs,simm
327
  example:      stb  $1,$2,1234
328
  operation:    The sign-extended immediate constant simm is added to the
329
                contents of register rs to form an effective memory address.
330
                The contents of register rd (the lowest 8 bits) are stored
331
                as a byte to this address.
332
 
333
 
334
Interrupts and Exceptions
335
-------------------------
336
 
337
There are neither interrupts nor exceptions in this version of ECO32e.
338
Unknown opcodes should nevertheless be recognized. A CPU simulation can
339
then report the execution of an unknown opcode; an implementation may
340
trap such an execution in a state of its controller which cannot be left
341
without reset.
342
 
343
 
344
Peripherals
345
-----------
346
 
347
Peripherals are memory-mapped. They need only support word accesses.
348
A sensible reaction to accesses with smaller widths (halfword or byte)
349
is not required.
350
 
351
In this version of ECO32e there are only two peripherals: a character
352
display and a keyboard.
353
 
354
The character display is capable of showing 30 lines with 80 characters
355
each. Its base address is 0x30100000. Each line occupies 128 words in
356
the I/O address space, one word for each column (and 48 unusable columns
357
at the end of the line). Therefore the address to which a character is
358
written and its location on the screen are related as follows:
359
    address = 0x30100000 + (line * 128 + column) * 4
360
The character to be displayed must be written as a word to the corresponding
361
address with its ASCII code contained in the lowest 8 bits of the word.
362
 
363
The keyboard is represented by two I/O registers. The status register
364
is located at address 0x30200000. When read (32 bits), its LSB indicates
365
if a character has been received from the physical keyboard. If this bit
366
is 1, the character can be read at address 0x30200004, the address of
367
the data register. By reading this latter address, the LSB of the
368
status register is automatically reset to 0. The data register must be
369
read with a word read; the character read is contained in the lowest
370
8 bits of the word.
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