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//----------------------------------------------------------------------------
// Copyright (C) 2009 , Olivier Girard
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//     * Redistributions of source code must retain the above copyright
//       notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above copyright
//       notice, this list of conditions and the following disclaimer in the
//       documentation and/or other materials provided with the distribution.
//     * Neither the name of the authors nor the names of its contributors
//       may be used to endorse or promote products derived from this software
//       without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
// OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
// THE POSSIBILITY OF SUCH DAMAGE
//
//----------------------------------------------------------------------------
//
// *File Name: omsp_alu.v
//
// *Module Description:
//                       openMSP430 ALU
//
// *Author(s):
//              - Olivier Girard,    olgirard@gmail.com
//
//----------------------------------------------------------------------------
// $Rev$
// $LastChangedBy$
// $LastChangedDate$
//----------------------------------------------------------------------------
`ifdef OMSP_NO_INCLUDE
`else
`include "openMSP430_defines.v"
`endif
 
module  omsp_alu (
 
// OUTPUTs
    alu_out,                       // ALU output value
    alu_out_add,                   // ALU adder output value
    alu_stat,                      // ALU Status {V,N,Z,C}
    alu_stat_wr,                   // ALU Status write {V,N,Z,C}
 
// INPUTs
    dbg_halt_st,                   // Halt/Run status from CPU
    exec_cycle,                    // Instruction execution cycle
    inst_alu,                      // ALU control signals
    inst_bw,                       // Decoded Inst: byte width
    inst_jmp,                      // Decoded Inst: Conditional jump
    inst_so,                       // Single-operand arithmetic
    op_dst,                        // Destination operand
    op_src,                        // Source operand
    status                         // R2 Status {V,N,Z,C}
);
 
// OUTPUTs
//=========
output       [15:0] alu_out;       // ALU output value
output       [15:0] alu_out_add;   // ALU adder output value
output        [3:0] alu_stat;      // ALU Status {V,N,Z,C}
output        [3:0] alu_stat_wr;   // ALU Status write {V,N,Z,C}
 
// INPUTs
//=========
input               dbg_halt_st;   // Halt/Run status from CPU
input               exec_cycle;    // Instruction execution cycle
input        [11:0] inst_alu;      // ALU control signals
input               inst_bw;       // Decoded Inst: byte width
input         [7:0] inst_jmp;      // Decoded Inst: Conditional jump
input         [7:0] inst_so;       // Single-operand arithmetic
input        [15:0] op_dst;        // Destination operand
input        [15:0] op_src;        // Source operand
input         [3:0] status;        // R2 Status {V,N,Z,C}
 
 
//=============================================================================
// 1)  FUNCTIONS
//=============================================================================
 
function [4:0] bcd_add;
 
   input [3:0] X;
   input [3:0] Y;
   input       C_;
 
   reg   [4:0] Z_;
   begin
      Z_ = {1'b0,X}+{1'b0,Y}+{4'b0000,C_};
      if (Z_<5'd10) bcd_add = Z_;
      else          bcd_add = Z_+5'd6;
   end
 
endfunction
 
 
//=============================================================================
// 2)  INSTRUCTION FETCH/DECODE CONTROL STATE MACHINE
//=============================================================================
// SINGLE-OPERAND ARITHMETIC:
//-----------------------------------------------------------------------------
//   Mnemonic   S-Reg,   Operation                               Status bits
//              D-Reg,                                            V  N  Z  C
//
//   RRC         dst     C->MSB->...LSB->C                        *  *  *  *
//   RRA         dst     MSB->MSB->...LSB->C                      0  *  *  *
//   SWPB        dst     Swap bytes                               -  -  -  -
//   SXT         dst     Bit7->Bit8...Bit15                       0  *  *  *
//   PUSH        src     SP-2->SP, src->@SP                       -  -  -  -
//   CALL        dst     SP-2->SP, PC+2->@SP, dst->PC             -  -  -  -
//   RETI                TOS->SR, SP+2->SP, TOS->PC, SP+2->SP     *  *  *  *
//
//-----------------------------------------------------------------------------
// TWO-OPERAND ARITHMETIC:
//-----------------------------------------------------------------------------
//   Mnemonic   S-Reg,   Operation                               Status bits
//              D-Reg,                                            V  N  Z  C
//
//   MOV       src,dst    src            -> dst                   -  -  -  -
//   ADD       src,dst    src +  dst     -> dst                   *  *  *  *
//   ADDC      src,dst    src +  dst + C -> dst                   *  *  *  *
//   SUB       src,dst    dst + ~src + 1 -> dst                   *  *  *  *
//   SUBC      src,dst    dst + ~src + C -> dst                   *  *  *  *
//   CMP       src,dst    dst + ~src + 1                          *  *  *  *
//   DADD      src,dst    src +  dst + C -> dst (decimaly)        *  *  *  *
//   BIT       src,dst    src &  dst                              0  *  *  *
//   BIC       src,dst   ~src &  dst     -> dst                   -  -  -  -
//   BIS       src,dst    src |  dst     -> dst                   -  -  -  -
//   XOR       src,dst    src ^  dst     -> dst                   *  *  *  *
//   AND       src,dst    src &  dst     -> dst                   0  *  *  *
//
//-----------------------------------------------------------------------------
// * the status bit is affected
// - the status bit is not affected
// 0 the status bit is cleared
// 1 the status bit is set
//-----------------------------------------------------------------------------
 
// Invert source for substract and compare instructions.
wire        op_src_inv_cmd = exec_cycle & (inst_alu[`ALU_SRC_INV]);
wire [15:0] op_src_inv     = {16{op_src_inv_cmd}} ^ op_src;
 
 
// Mask the bit 8 for the Byte instructions for correct flags generation
wire        op_bit8_msk     = ~exec_cycle | ~inst_bw;
wire [16:0] op_src_in       = {1'b0, {op_src_inv[15:8] & {8{op_bit8_msk}}}, op_src_inv[7:0]};
wire [16:0] op_dst_in       = {1'b0, {op_dst[15:8]     & {8{op_bit8_msk}}}, op_dst[7:0]};
 
// Clear the source operand (= jump offset) for conditional jumps
wire        jmp_not_taken  = (inst_jmp[`JL]  & ~(status[3]^status[2])) |
                             (inst_jmp[`JGE] &  (status[3]^status[2])) |
                             (inst_jmp[`JN]  &  ~status[2])            |
                             (inst_jmp[`JC]  &  ~status[0])            |
                             (inst_jmp[`JNC] &   status[0])            |
                             (inst_jmp[`JEQ] &  ~status[1])            |
                             (inst_jmp[`JNE] &   status[1]);
wire [16:0] op_src_in_jmp  = op_src_in & {17{~jmp_not_taken}};
 
// Adder / AND / OR / XOR
wire [16:0] alu_add        = op_src_in_jmp + op_dst_in;
wire [16:0] alu_and        = op_src_in     & op_dst_in;
wire [16:0] alu_or         = op_src_in     | op_dst_in;
wire [16:0] alu_xor        = op_src_in     ^ op_dst_in;
 
 
// Incrementer
wire        alu_inc         = exec_cycle & ((inst_alu[`ALU_INC_C] & status[0]) |
                                             inst_alu[`ALU_INC]);
wire [16:0] alu_add_inc    = alu_add + {16'h0000, alu_inc};
 
 
 
// Decimal adder (DADD)
wire  [4:0] alu_dadd0      = bcd_add(op_src_in[3:0],   op_dst_in[3:0],  status[0]);
wire  [4:0] alu_dadd1      = bcd_add(op_src_in[7:4],   op_dst_in[7:4],  alu_dadd0[4]);
wire  [4:0] alu_dadd2      = bcd_add(op_src_in[11:8],  op_dst_in[11:8], alu_dadd1[4]);
wire  [4:0] alu_dadd3      = bcd_add(op_src_in[15:12], op_dst_in[15:12],alu_dadd2[4]);
wire [16:0] alu_dadd       = {alu_dadd3, alu_dadd2[3:0], alu_dadd1[3:0], alu_dadd0[3:0]};
 
 
// Shifter for rotate instructions (RRC & RRA)
wire        alu_shift_msb  = inst_so[`RRC] ? status[0]     :
                             inst_bw       ? op_src[7]     : op_src[15];
wire        alu_shift_7    = inst_bw       ? alu_shift_msb : op_src[8];
wire [16:0] alu_shift      = {1'b0, alu_shift_msb, op_src[15:9], alu_shift_7, op_src[7:1]};
 
 
// Swap bytes / Extend Sign
wire [16:0] alu_swpb       = {1'b0, op_src[7:0],op_src[15:8]};
wire [16:0] alu_sxt        = {1'b0, {8{op_src[7]}},op_src[7:0]};
 
 
// Combine short paths toghether to simplify final ALU mux
wire        alu_short_thro = ~(inst_alu[`ALU_AND]   |
                               inst_alu[`ALU_OR]    |
                               inst_alu[`ALU_XOR]   |
                               inst_alu[`ALU_SHIFT] |
                               inst_so[`SWPB]       |
                               inst_so[`SXT]);
 
wire [16:0] alu_short      = ({17{inst_alu[`ALU_AND]}}   & alu_and)   |
                             ({17{inst_alu[`ALU_OR]}}    & alu_or)    |
                             ({17{inst_alu[`ALU_XOR]}}   & alu_xor)   |
                             ({17{inst_alu[`ALU_SHIFT]}} & alu_shift) |
                             ({17{inst_so[`SWPB]}}       & alu_swpb)  |
                             ({17{inst_so[`SXT]}}        & alu_sxt)   |
                             ({17{alu_short_thro}}       & op_src_in);
 
 
// ALU output mux
wire [16:0] alu_out_nxt    = (inst_so[`IRQ] | dbg_halt_st |
                              inst_alu[`ALU_ADD]) ? alu_add_inc :
                              inst_alu[`ALU_DADD] ? alu_dadd    : alu_short;
 
assign      alu_out        =  alu_out_nxt[15:0];
assign      alu_out_add    =  alu_add[15:0];
 
 
//-----------------------------------------------------------------------------
// STATUS FLAG GENERATION
//-----------------------------------------------------------------------------
 
wire    V_xor       = inst_bw ? (op_src_in[7]  & op_dst_in[7])  :
                                (op_src_in[15] & op_dst_in[15]);
 
wire    V           = inst_bw ? ((~op_src_in[7]  & ~op_dst_in[7]  &  alu_out[7])  |
                                 ( op_src_in[7]  &  op_dst_in[7]  & ~alu_out[7])) :
                                ((~op_src_in[15] & ~op_dst_in[15] &  alu_out[15]) |
                                 ( op_src_in[15] &  op_dst_in[15] & ~alu_out[15]));
 
wire    N           = inst_bw ?  alu_out[7]       : alu_out[15];
wire    Z           = inst_bw ? (alu_out[7:0]==0) : (alu_out==0);
wire    C           = inst_bw ?  alu_out[8]       : alu_out_nxt[16];
 
assign  alu_stat    = inst_alu[`ALU_SHIFT]  ? {1'b0, N,Z,op_src_in[0]} :
                      inst_alu[`ALU_STAT_7] ? {1'b0, N,Z,~Z}           :
                      inst_alu[`ALU_XOR]    ? {V_xor,N,Z,~Z}           : {V,N,Z,C};
 
assign  alu_stat_wr = (inst_alu[`ALU_STAT_F] & exec_cycle) ? 4'b1111 : 4'b0000;
 
 
// LINT cleanup
wire    UNUSED_inst_so_rra  = inst_so[`RRA];
wire    UNUSED_inst_so_push = inst_so[`PUSH];
wire    UNUSED_inst_so_call = inst_so[`CALL];
wire    UNUSED_inst_so_reti = inst_so[`RETI];
wire    UNUSED_inst_jmp     = inst_jmp[`JMP];
wire    UNUSED_inst_alu     = inst_alu[`EXEC_NO_WR];
 
endmodule // omsp_alu
 
`ifdef OMSP_NO_INCLUDE
`else
`include "openMSP430_undefines.v"
`endif

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[/] [openmsp430/] [trunk/] [fpga/] [xilinx_avnet_lx9microbard/] [rtl/] [verilog/] [openmsp430/] [omsp_alu.v] - Blame information for rev 205

Line No.	Rev	Author	Line
1	157	olivier.gi	`//----------------------------------------------------------------------------`
2			`// Copyright (C) 2009 , Olivier Girard`
3			`//`
4			`// Redistribution and use in source and binary forms, with or without`
5			`// modification, are permitted provided that the following conditions`
6			`// are met:`
7			`// * Redistributions of source code must retain the above copyright`
8			`// notice, this list of conditions and the following disclaimer.`
9			`// * Redistributions in binary form must reproduce the above copyright`
10			`// notice, this list of conditions and the following disclaimer in the`
11			`// documentation and/or other materials provided with the distribution.`
12			`// * Neither the name of the authors nor the names of its contributors`
13			`// may be used to endorse or promote products derived from this software`
14			`// without specific prior written permission.`
15			`//`
16			`// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"`
17			`// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE`
18			`// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE`
19			`// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE`
20			`// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,`
21			`// OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF`
22			`// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS`
23			`// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN`
24			`// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)`
25			`// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF`
26			`// THE POSSIBILITY OF SUCH DAMAGE`
27			`//`
28			`//----------------------------------------------------------------------------`
29			`//`
30			`// *File Name: omsp_alu.v`
31	202	olivier.gi	`//`
32	157	olivier.gi	`// *Module Description:`
33			`// openMSP430 ALU`
34			`//`
35			`// *Author(s):`
36			`// - Olivier Girard, olgirard@gmail.com`
37			`//`
38			`//----------------------------------------------------------------------------`
39	202	olivier.gi	`// $Rev$`
40			`// $LastChangedBy$`
41			`// $LastChangedDate$`
42	157	olivier.gi	`//----------------------------------------------------------------------------`
43			`ifdef OMSP_NO_INCLUDE
44			`else
45			`include "openMSP430_defines.v"
46			`endif
47
48			`module omsp_alu (`
49
50			`// OUTPUTs`
51			`alu_out, // ALU output value`
52			`alu_out_add, // ALU adder output value`
53			`alu_stat, // ALU Status {V,N,Z,C}`
54			`alu_stat_wr, // ALU Status write {V,N,Z,C}`
55
56			`// INPUTs`
57			`dbg_halt_st, // Halt/Run status from CPU`
58			`exec_cycle, // Instruction execution cycle`
59			`inst_alu, // ALU control signals`
60			`inst_bw, // Decoded Inst: byte width`
61			`inst_jmp, // Decoded Inst: Conditional jump`
62			`inst_so, // Single-operand arithmetic`
63			`op_dst, // Destination operand`
64			`op_src, // Source operand`
65			`status // R2 Status {V,N,Z,C}`
66			`);`
67
68			`// OUTPUTs`
69			`//=========`
70			`output [15:0] alu_out; // ALU output value`
71			`output [15:0] alu_out_add; // ALU adder output value`
72			`output [3:0] alu_stat; // ALU Status {V,N,Z,C}`
73			`output [3:0] alu_stat_wr; // ALU Status write {V,N,Z,C}`
74
75			`// INPUTs`
76			`//=========`
77			`input dbg_halt_st; // Halt/Run status from CPU`
78			`input exec_cycle; // Instruction execution cycle`
79			`input [11:0] inst_alu; // ALU control signals`
80			`input inst_bw; // Decoded Inst: byte width`
81			`input [7:0] inst_jmp; // Decoded Inst: Conditional jump`
82			`input [7:0] inst_so; // Single-operand arithmetic`
83			`input [15:0] op_dst; // Destination operand`
84			`input [15:0] op_src; // Source operand`
85			`input [3:0] status; // R2 Status {V,N,Z,C}`
86
87
88			`//=============================================================================`
89			`// 1) FUNCTIONS`
90			`//=============================================================================`
91
92			`function [4:0] bcd_add;`
93
94			`input [3:0] X;`
95			`input [3:0] Y;`
96			`input C_;`
97
98			`reg [4:0] Z_;`
99			`begin`
100	193	olivier.gi	`Z_ = {1'b0,X}+{1'b0,Y}+{4'b0000,C_};`
101	157	olivier.gi	`if (Z_<5'd10) bcd_add = Z_;`
102			`else bcd_add = Z_+5'd6;`
103			`end`
104
105			`endfunction`
106
107
108			`//=============================================================================`
109			`// 2) INSTRUCTION FETCH/DECODE CONTROL STATE MACHINE`
110			`//=============================================================================`
111			`// SINGLE-OPERAND ARITHMETIC:`
112			`//-----------------------------------------------------------------------------`
113			`// Mnemonic S-Reg, Operation Status bits`
114			`// D-Reg, V N Z C`
115			`//`
116			`// RRC dst C->MSB->...LSB->C * * * *`
117			`// RRA dst MSB->MSB->...LSB->C 0 * * *`
118			`// SWPB dst Swap bytes - - - -`
119			`// SXT dst Bit7->Bit8...Bit15 0 * * *`
120			`// PUSH src SP-2->SP, src->@SP - - - -`
121			`// CALL dst SP-2->SP, PC+2->@SP, dst->PC - - - -`
122			`// RETI TOS->SR, SP+2->SP, TOS->PC, SP+2->SP * * * *`
123			`//`
124			`//-----------------------------------------------------------------------------`
125			`// TWO-OPERAND ARITHMETIC:`
126			`//-----------------------------------------------------------------------------`
127			`// Mnemonic S-Reg, Operation Status bits`
128			`// D-Reg, V N Z C`
129			`//`
130			`// MOV src,dst src -> dst - - - -`
131			`// ADD src,dst src + dst -> dst * * * *`
132			`// ADDC src,dst src + dst + C -> dst * * * *`
133			`// SUB src,dst dst + ~src + 1 -> dst * * * *`
134			`// SUBC src,dst dst + ~src + C -> dst * * * *`
135			`// CMP src,dst dst + ~src + 1 * * * *`
136			`// DADD src,dst src + dst + C -> dst (decimaly) * * * *`
137			`// BIT src,dst src & dst 0 * * *`
138			`// BIC src,dst ~src & dst -> dst - - - -`
139			`// BIS src,dst src \| dst -> dst - - - -`
140			`// XOR src,dst src ^ dst -> dst * * * *`
141			`// AND src,dst src & dst -> dst 0 * * *`
142			`//`
143			`//-----------------------------------------------------------------------------`
144			`// * the status bit is affected`
145			`// - the status bit is not affected`
146			`// 0 the status bit is cleared`
147			`// 1 the status bit is set`
148			`//-----------------------------------------------------------------------------`
149
150			`// Invert source for substract and compare instructions.`
151			wire op_src_inv_cmd = exec_cycle & (inst_alu[`ALU_SRC_INV]);
152			`wire [15:0] op_src_inv = {16{op_src_inv_cmd}} ^ op_src;`
153
154
155			`// Mask the bit 8 for the Byte instructions for correct flags generation`
156			`wire op_bit8_msk = ~exec_cycle \| ~inst_bw;`
157			`wire [16:0] op_src_in = {1'b0, {op_src_inv[15:8] & {8{op_bit8_msk}}}, op_src_inv[7:0]};`
158			`wire [16:0] op_dst_in = {1'b0, {op_dst[15:8] & {8{op_bit8_msk}}}, op_dst[7:0]};`
159
160			`// Clear the source operand (= jump offset) for conditional jumps`
161			wire jmp_not_taken = (inst_jmp[`JL] & ~(status[3]^status[2])) \|
162			(inst_jmp[`JGE] & (status[3]^status[2])) \|
163			(inst_jmp[`JN] & ~status[2]) \|
164			(inst_jmp[`JC] & ~status[0]) \|
165			(inst_jmp[`JNC] & status[0]) \|
166			(inst_jmp[`JEQ] & ~status[1]) \|
167			(inst_jmp[`JNE] & status[1]);
168			`wire [16:0] op_src_in_jmp = op_src_in & {17{~jmp_not_taken}};`
169
170			`// Adder / AND / OR / XOR`
171			`wire [16:0] alu_add = op_src_in_jmp + op_dst_in;`
172			`wire [16:0] alu_and = op_src_in & op_dst_in;`
173			`wire [16:0] alu_or = op_src_in \| op_dst_in;`
174			`wire [16:0] alu_xor = op_src_in ^ op_dst_in;`
175
176
177			`// Incrementer`
178			wire alu_inc = exec_cycle & ((inst_alu[`ALU_INC_C] & status[0]) \|
179			inst_alu[`ALU_INC]);
180			`wire [16:0] alu_add_inc = alu_add + {16'h0000, alu_inc};`
181
182
183
184			`// Decimal adder (DADD)`
185			`wire [4:0] alu_dadd0 = bcd_add(op_src_in[3:0], op_dst_in[3:0], status[0]);`
186			`wire [4:0] alu_dadd1 = bcd_add(op_src_in[7:4], op_dst_in[7:4], alu_dadd0[4]);`
187			`wire [4:0] alu_dadd2 = bcd_add(op_src_in[11:8], op_dst_in[11:8], alu_dadd1[4]);`
188			`wire [4:0] alu_dadd3 = bcd_add(op_src_in[15:12], op_dst_in[15:12],alu_dadd2[4]);`
189			`wire [16:0] alu_dadd = {alu_dadd3, alu_dadd2[3:0], alu_dadd1[3:0], alu_dadd0[3:0]};`
190
191
192			`// Shifter for rotate instructions (RRC & RRA)`
193			wire alu_shift_msb = inst_so[`RRC] ? status[0] :
194	202	olivier.gi	`inst_bw ? op_src[7] : op_src[15];`
195	157	olivier.gi	`wire alu_shift_7 = inst_bw ? alu_shift_msb : op_src[8];`
196			`wire [16:0] alu_shift = {1'b0, alu_shift_msb, op_src[15:9], alu_shift_7, op_src[7:1]};`
197
198
199			`// Swap bytes / Extend Sign`
200			`wire [16:0] alu_swpb = {1'b0, op_src[7:0],op_src[15:8]};`
201			`wire [16:0] alu_sxt = {1'b0, {8{op_src[7]}},op_src[7:0]};`
202
203
204			`// Combine short paths toghether to simplify final ALU mux`
205			wire alu_short_thro = ~(inst_alu[`ALU_AND] \|
206			inst_alu[`ALU_OR] \|
207			inst_alu[`ALU_XOR] \|
208			inst_alu[`ALU_SHIFT] \|
209			inst_so[`SWPB] \|
210			inst_so[`SXT]);
211
212			wire [16:0] alu_short = ({17{inst_alu[`ALU_AND]}} & alu_and) \|
213			({17{inst_alu[`ALU_OR]}} & alu_or) \|
214			({17{inst_alu[`ALU_XOR]}} & alu_xor) \|
215			({17{inst_alu[`ALU_SHIFT]}} & alu_shift) \|
216			({17{inst_so[`SWPB]}} & alu_swpb) \|
217			({17{inst_so[`SXT]}} & alu_sxt) \|
218			`({17{alu_short_thro}} & op_src_in);`
219
220
221			`// ALU output mux`
222			wire [16:0] alu_out_nxt = (inst_so[`IRQ] \| dbg_halt_st \|
223			inst_alu[`ALU_ADD]) ? alu_add_inc :
224			inst_alu[`ALU_DADD] ? alu_dadd : alu_short;
225
226			`assign alu_out = alu_out_nxt[15:0];`
227			`assign alu_out_add = alu_add[15:0];`
228
229
230			`//-----------------------------------------------------------------------------`
231			`// STATUS FLAG GENERATION`
232			`//-----------------------------------------------------------------------------`
233
234			`wire V_xor = inst_bw ? (op_src_in[7] & op_dst_in[7]) :`
235			`(op_src_in[15] & op_dst_in[15]);`
236
237			`wire V = inst_bw ? ((~op_src_in[7] & ~op_dst_in[7] & alu_out[7]) \|`
238			`( op_src_in[7] & op_dst_in[7] & ~alu_out[7])) :`
239			`((~op_src_in[15] & ~op_dst_in[15] & alu_out[15]) \|`
240			`( op_src_in[15] & op_dst_in[15] & ~alu_out[15]));`
241
242			`wire N = inst_bw ? alu_out[7] : alu_out[15];`
243			`wire Z = inst_bw ? (alu_out[7:0]==0) : (alu_out==0);`
244			`wire C = inst_bw ? alu_out[8] : alu_out_nxt[16];`
245
246			assign alu_stat = inst_alu[`ALU_SHIFT] ? {1'b0, N,Z,op_src_in[0]} :
247			inst_alu[`ALU_STAT_7] ? {1'b0, N,Z,~Z} :
248			inst_alu[`ALU_XOR] ? {V_xor,N,Z,~Z} : {V,N,Z,C};
249
250			assign alu_stat_wr = (inst_alu[`ALU_STAT_F] & exec_cycle) ? 4'b1111 : 4'b0000;
251
252
253	202	olivier.gi	`// LINT cleanup`
254			wire UNUSED_inst_so_rra = inst_so[`RRA];
255			wire UNUSED_inst_so_push = inst_so[`PUSH];
256			wire UNUSED_inst_so_call = inst_so[`CALL];
257			wire UNUSED_inst_so_reti = inst_so[`RETI];
258			wire UNUSED_inst_jmp = inst_jmp[`JMP];
259			wire UNUSED_inst_alu = inst_alu[`EXEC_NO_WR];
260
261	157	olivier.gi	`endmodule // omsp_alu`
262
263			`ifdef OMSP_NO_INCLUDE
264			`else
265			`include "openMSP430_undefines.v"
266			`endif