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Kevin Kim 2023-02-11 21:22:33 -08:00
parent 420a0209dd
commit 857097282c
2 changed files with 32 additions and 116 deletions
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97
src/ieu/alu.sv
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@ -32,78 +32,31 @@
module alu #(parameter WIDTH=32) ( module alu #(parameter WIDTH=32) (
input logic [WIDTH-1:0] A, B, // Operands input logic [WIDTH-1:0] A, B, // Operands
input logic [2:0] ALUControl, // With Funct3, indicates operation to perform input logic [2:0] ALUControl, // With Funct3, indicates operation to perform
input logic [6:0] Funct7, input logic [6:0] Funct7, // Funct7 from execute stage
input logic [2:0] Funct3, // With ALUControl, indicates operation to perform input logic [2:0] Funct3, // With ALUControl, indicates operation to perform
output logic [WIDTH-1:0] Result, // ALU result output logic [WIDTH-1:0] Result, // ALU result
output logic [WIDTH-1:0] Sum); // Sum of operands output logic [WIDTH-1:0] Sum); // Sum of operands
// CondInvB = ~B when subtracting or inverted operand instruction in ZBB, B otherwise. Shift = shift result. SLT/U = result of a slt/u instruction. // CondInvB = ~B when subtracting, B otherwise. Shift = shift result. SLT/U = result of a slt/u instruction.
// FullResult = ALU result before adjusting for a RV64 w-suffix instruction. // FullResult = ALU result before adjusting for a RV64 w-suffix instruction.
logic [WIDTH-1:0] ZBBResult, ZBSResult; logic [WIDTH-1:0] CondInvB, Shift, SLT, SLTU, FullResult; // Intermediate results
logic [WIDTH-1:0] CondInvB, Shift, SLT, SLTU, FullResult, CondShiftA, ALUResult; // Intermediate results
logic Carry, Neg; // Flags: carry out, negative logic Carry, Neg; // Flags: carry out, negative
logic LT, LTU; // Less than, Less than unsigned logic LT, LTU; // Less than, Less than unsigned
logic W64; // RV64 W-type instruction logic W64; // RV64 W-type instruction
logic SubArith; // Performing subtraction or arithmetic right shift logic SubArith; // Performing subtraction or arithmetic right shift
logic ALUOp; // 0 for address generation addition or 1 for regular ALU ops logic ALUOp; // 0 for address generation addition or 1 for regular ALU ops
logic Asign, Bsign; // Sign bits of A, B logic Asign, Bsign; // Sign bits of A, B
logic InvB; // Is Inverted Operand Instruction (ZBB) logic rotate;
logic Rotate; // Is rotate operation
logic ZbaAdd; // Is ZBA Add Operation
// Extract control signals from ALUControl. // Extract control signals from ALUControl.
assign {W64, SubArith, ALUOp} = ALUControl; assign {W64, SubArith, ALUOp} = ALUControl;
// Addition // Addition
if (`ZBA_SUPPORTED) assign CondInvB = SubArith ? ~B : B;
always_comb begin assign {Carry, Sum} = A + CondInvB + {{(WIDTH-1){1'b0}}, SubArith};
ZbaAdd = (Funct7 == 7'b0010000 | Funct7 == 7'b0000100);
case({Funct7, Funct3, W64})
11'b0010000_010_0: CondShiftA = {A[WIDTH-2:0], {1'b0}}; //sh1add
11'b0010000_100_0: CondShiftA = {A[WIDTH-3:0], {2'b00}}; //sh2add
11'b0010000_110_0: CondShiftA = {A[WIDTH-4:0], {3'b000}}; //sh3add
11'b0000100_000_1: CondShiftA = {{32{1'b0}}, A[31:0]}; //add.uw
11'b0010000_010_1: CondShiftA = {{31{1'b0}},A[31:0], {1'b0}}; //sh1add.uw
11'b0010000_100_1: CondShiftA = {{30{1'b0}},A[31:0], {2'b00}}; //sh2add.uw
11'b0010000_110_1: CondShiftA = {{29{1'b0}},A[31:0], {3'b000}}; //sh3add.uw
default: CondShiftA = A;
endcase
end
else begin
assign CondShiftA = A;
assign ZbaAdd = 0;
end
if (`ZBB_SUPPORTED)
always_comb begin
case ({Funct7,Funct3})
10'b0100000_111: InvB = 1'b0; //andn
10'b0100000_110: InvB = 1'b0; //orn
10'b0100000_100: InvB = 1'b0; //xnor
default: InvB = 1'b0;
endcase
casez ({Funct7, Funct3})
10'b011000?_101: Rotate = 1'b1;
10'b000010?_001: Rotate = 1'b0;
10'b0110000_001: Rotate = 1'b1;
default: Rotate = 1'b0;
endcase
end
else begin
assign InvB = 1'b0;
assign Rotate = 1'b0;
end
assign CondInvB = (SubArith | InvB) ? ~B : B;
assign {Carry, Sum} = CondShiftA + CondInvB + {{(WIDTH-1){1'b0}}, SubArith};
// Shifts // Shifts
shifter sh(.A, .Amt(B[`LOG_XLEN-1:0]), .Right(Funct3[2]), .Arith(SubArith), .W64, .Rotate(Rotate), .Y(Shift)); shifter sh(.A, .Amt(B[`LOG_XLEN-1:0]), .Right(Funct3[2]), .Arith(SubArith), .W64, .Y(Shift), .Rotate(rotate));
// Condition code flags are based on subtraction output Sum = A-B. // Condition code flags are based on subtraction output Sum = A-B.
// Overflow occurs when the numbers being subtracted have the opposite sign // Overflow occurs when the numbers being subtracted have the opposite sign
@ -121,42 +74,18 @@ module alu #(parameter WIDTH=32) (
// Select appropriate ALU Result // Select appropriate ALU Result
always_comb always_comb
if (~ALUOp | ZbaAdd) FullResult = Sum; // Always add for ALUOp = 0 (address generation) and ZBA if (~ALUOp) FullResult = Sum; // Always add for ALUOp = 0 (address generation)
else casez (Funct3) // Otherwise check Funct3 else casez (Funct3) // Otherwise check Funct3
3'b000: FullResult = Sum; // add or sub 3'b000: FullResult = Sum; // add or sub
3'b?01: FullResult = Shift; // sll, sra, or srl 3'b?01: FullResult = Shift; // sll, sra, or srl
3'b010: FullResult = SLT; // slt 3'b010: FullResult = SLT; // slt
3'b011: FullResult = SLTU; // sltu 3'b011: FullResult = SLTU; // sltu
3'b100: FullResult = A ^ CondInvB; // xor 3'b100: FullResult = A ^ B; // xor
3'b110: FullResult = A | CondInvB; // or 3'b110: FullResult = A | B; // or
3'b111: FullResult = A & CondInvB; // and 3'b111: FullResult = A & B; // and
endcase endcase
if (`ZBS_SUPPORTED)
zbs #(WIDTH) zbs(.A, .B, .Funct7, .Funct3, .ZBSResult);
else assign ZBSResult = 0;
if (`ZBB_SUPPORTED)
zbb #(WIDTH) zbb(.A, .B, .Funct3, .Funct7, .W64, .ZBBResult);
else assign ZBBResult = 0;
// Support RV64I W-type addw/subw/addiw/shifts that discard upper 32 bits and sign-extend 32-bit result to 64 bits // Support RV64I W-type addw/subw/addiw/shifts that discard upper 32 bits and sign-extend 32-bit result to 64 bits
if (WIDTH == 64) assign ALUResult = (W64 & ~ZbaAdd) ? {{32{FullResult[31]}}, FullResult[31:0]} : FullResult; if (WIDTH == 64) assign Result = W64 ? {{32{FullResult[31]}}, FullResult[31:0]} : FullResult;
else assign ALUResult = FullResult; else assign Result = FullResult;
if (`ZBB_SUPPORTED | `ZBA_SUPPORTED | `ZBS_SUPPORTED | `ZBC_SUPPORTED) begin
always_comb
casez({Funct7})
7'b010010?: Result = ZBSResult;
7'b001010?: Result = ZBSResult;
default: Result = ALUResult;
endcase
end else begin
assign Result = ALUResult;
end
endmodule endmodule

21
src/ieu/controller.sv
View File

@ -149,7 +149,7 @@ module controller(
ControlsD = `CTRLW'b1_101_01_11_001_0_0_0_0_0_0_0_0_0_10_0; // amo ControlsD = `CTRLW'b1_101_01_11_001_0_0_0_0_0_0_0_0_0_10_0; // amo
end else end else
ControlsD = `CTRLW'b0_000_00_00_000_0_0_0_0_0_0_0_0_0_00_1; // Non-implemented instruction ControlsD = `CTRLW'b0_000_00_00_000_0_0_0_0_0_0_0_0_0_00_1; // Non-implemented instruction
7'b0110011: if (Funct7D == 7'b0000000 | Funct7D == 7'b0100000 | (Funct7D == 7'b0010000 & `ZBA_SUPPORTED) | (Funct7D == 7'b0100100 & `ZBS_SUPPORTED)) 7'b0110011: if (Funct7D == 7'b0000000 | Funct7D == 7'b0100000)
ControlsD = `CTRLW'b1_000_00_00_000_0_1_0_0_0_0_0_0_0_00_0; // R-type ControlsD = `CTRLW'b1_000_00_00_000_0_1_0_0_0_0_0_0_0_00_0; // R-type
else if (Funct7D == 7'b0000001 & `M_SUPPORTED) else if (Funct7D == 7'b0000001 & `M_SUPPORTED)
ControlsD = `CTRLW'b1_000_00_00_011_0_0_0_0_0_0_0_0_1_00_0; // Multiply/divide ControlsD = `CTRLW'b1_000_00_00_011_0_0_0_0_0_0_0_0_1_00_0; // Multiply/divide
@ -160,9 +160,6 @@ module controller(
ControlsD = `CTRLW'b1_000_00_00_000_0_1_0_0_1_0_0_0_0_00_0; // R-type W instructions for RV64i ControlsD = `CTRLW'b1_000_00_00_000_0_1_0_0_1_0_0_0_0_00_0; // R-type W instructions for RV64i
else if (Funct7D == 7'b0000001 & `M_SUPPORTED & `XLEN == 64) else if (Funct7D == 7'b0000001 & `M_SUPPORTED & `XLEN == 64)
ControlsD = `CTRLW'b1_000_00_00_011_0_0_0_0_1_0_0_0_1_00_0; // W-type Multiply/Divide ControlsD = `CTRLW'b1_000_00_00_011_0_0_0_0_1_0_0_0_1_00_0; // W-type Multiply/Divide
else
if ((Funct7D == 7'b0000100 | Funct7D == 7'b0010000) & `ZBA_SUPPORTED)
ControlsD = `CTRLW'b1_000_00_00_000_0_1_0_0_1_0_0_0_0_00_0; // adduw, sh1adduw, sh2adduw, sh3adduw
else else
ControlsD = `CTRLW'b0_000_00_00_000_0_0_0_0_0_0_0_0_0_00_1; // Non-implemented instruction ControlsD = `CTRLW'b0_000_00_00_000_0_0_0_0_0_0_0_0_0_00_1; // Non-implemented instruction
7'b1100011: ControlsD = `CTRLW'b0_010_11_00_000_1_0_0_0_0_0_0_0_0_00_0; // branches 7'b1100011: ControlsD = `CTRLW'b0_010_11_00_000_1_0_0_0_0_0_0_0_0_00_0; // branches
@ -193,15 +190,6 @@ module controller(
assign SFenceVmaD = PrivilegedD & (InstrD[31:25] == 7'b0001001); assign SFenceVmaD = PrivilegedD & (InstrD[31:25] == 7'b0001001);
assign FenceD = SFenceVmaD | FenceXD; // possible sfence.vma or fence.i assign FenceD = SFenceVmaD | FenceXD; // possible sfence.vma or fence.i
if (`ZBA_SUPPORTED) begin
// ALU Decoding is more comprehensive when ZBA is supported
assign sltD = (Funct3D == 3'b010 & OpD == 7'b0010011);
assign sltuD = (Funct3D == 3'b011 & OpD == 7'b0010011);
assign subD = (Funct3D == 3'b000 & Funct7D[5] & OpD[5]); // OpD[5] needed to distinguish sub from addi
assign sraD = (Funct3D == 3'b101 & Funct7D[5]);
assign SubArithD = ALUOpD & (subD | sraD | sltD | sltuD); // TRUE for R-type subtracts and sra, slt, sltu
assign ALUControlD = {W64D, SubArithD, ALUOpD};
end else begin
// ALU Decoding is lazy, only using func7[5] to distinguish add/sub and srl/sra // ALU Decoding is lazy, only using func7[5] to distinguish add/sub and srl/sra
assign sltD = (Funct3D == 3'b010); assign sltD = (Funct3D == 3'b010);
assign sltuD = (Funct3D == 3'b011); assign sltuD = (Funct3D == 3'b011);
@ -209,7 +197,6 @@ module controller(
assign sraD = (Funct3D == 3'b101 & Funct7D[5]); assign sraD = (Funct3D == 3'b101 & Funct7D[5]);
assign SubArithD = ALUOpD & (subD | sraD | sltD | sltuD); // TRUE for R-type subtracts and sra, slt, sltu assign SubArithD = ALUOpD & (subD | sraD | sltD | sltuD); // TRUE for R-type subtracts and sra, slt, sltu
assign ALUControlD = {W64D, SubArithD, ALUOpD}; assign ALUControlD = {W64D, SubArithD, ALUOpD};
end
// Fences // Fences
// Ordinary fence is presently a nop // Ordinary fence is presently a nop
@ -228,9 +215,9 @@ module controller(
flopenrc #(1) controlregD(clk, reset, FlushD, ~StallD, 1'b1, InstrValidD); flopenrc #(1) controlregD(clk, reset, FlushD, ~StallD, 1'b1, InstrValidD);
// Execute stage pipeline control register and logic // Execute stage pipeline control register and logic
flopenrc #(35) controlregE(clk, reset, FlushE, ~StallE, flopenrc #(28) controlregE(clk, reset, FlushE, ~StallE,
{RegWriteD, ResultSrcD, MemRWD, JumpD, BranchD, ALUControlD, ALUSrcAD, ALUSrcBD, ALUResultSrcD, CSRReadD, CSRWriteD, PrivilegedD, Funct3D, Funct7D, W64D, MDUD, AtomicD, InvalidateICacheD, FlushDCacheD, FenceD, InstrValidD}, {RegWriteD, ResultSrcD, MemRWD, JumpD, BranchD, ALUControlD, ALUSrcAD, ALUSrcBD, ALUResultSrcD, CSRReadD, CSRWriteD, PrivilegedD, Funct3D, W64D, MDUD, AtomicD, InvalidateICacheD, FlushDCacheD, FenceD, InstrValidD},
{IEURegWriteE, ResultSrcE, MemRWE, JumpE, BranchE, ALUControlE, ALUSrcAE, ALUSrcBE, ALUResultSrcE, CSRReadE, CSRWriteE, PrivilegedE, Funct3E, Funct7E, W64E, MDUE, AtomicE, InvalidateICacheE, FlushDCacheE, FenceE, InstrValidE}); {IEURegWriteE, ResultSrcE, MemRWE, JumpE, BranchE, ALUControlE, ALUSrcAE, ALUSrcBE, ALUResultSrcE, CSRReadE, CSRWriteE, PrivilegedE, Funct3E, W64E, MDUE, AtomicE, InvalidateICacheE, FlushDCacheE, FenceE, InstrValidE});
// Branch Logic // Branch Logic
// The comparator handles both signed and unsigned branches using BranchSignedE // The comparator handles both signed and unsigned branches using BranchSignedE