Files
Toooba/src_Core/ISA/ISA_Decls_CHERI.bsv
Franz Fuchs 6ebe612ff8 Fix Toooba to use addresses instead of offsets (#32)
* Fixed the Decoding of (C)JAL

* Use CSR addresses instead of offsets

* Fixed offsets correctly

* Fixed all offsets I could spot

* Fix use of modifyOffset function

* Corrected brAddrCalc function

* Preliminary fix for ddc offsetting

* Use setAddr instead of incOffset for DDC

* Deleted unnecessarily added lines in ALU pipeline

* Deleted white space

* Switched off verbosity for ALU pipeline

* Removed unnecessary print import
2025-02-05 11:06:07 +00:00

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/*
* Copyright (c) 2020 Peter Rugg
* Copyright (c) 2020 Jonathan Woodruff
* All rights reserved.
* This software was developed by SRI International and the University of
* Cambridge Computer Laboratory (Department of Computer Science and
* Technology) under DARPA contract HR0011-18-C-0016 ("ECATS"), as part of the
* DARPA SSITH research programme.
* This work was supported by NCSC programme grant 4212611/RFA 15971 ("SafeBet").
*
* @BERI_LICENSE_HEADER_START@
*
* Licensed to BERI Open Systems C.I.C. (BERI) under one or more contributor
* license agreements. See the NOTICE file distributed with this work for
* additional information regarding copyright ownership. BERI licenses this
* file to you under the BERI Hardware-Software License, Version 1.0 (the
* "License"); you may not use this file except in compliance with the
* License. You may obtain a copy of the License at:
*
* http://www.beri-open-systems.org/legal/license-1-0.txt
*
* Unless required by applicable law or agreed to in writing, Work distributed
* under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR
* CONDITIONS OF ANY KIND, either express or implied. See the License for the
* specific language governing permissions and limitations under the License.
*
* @BERI_LICENSE_HEADER_END@
*/
import ISA_Decls::*;
import CHERICap::*;
import CHERICC_Fat::*;
typedef TMul#(XLEN, 2) CLEN;
// Exception codes
typedef struct { Bit#(5) code; } CHERIException deriving(Bits, Eq);
`define CHERIException(n, v) CHERIException cheriExc``n = CHERIException { code: v };
`include "CHERIExceptions.bsvi"
`undef CHERIException
instance FShow#(CHERIException);
function Fmt fshow(CHERIException exc);
return (case(exc.code)
`define CHERIException(n, v) v: $format(`"``cheriExc``n```");
`include "CHERIExceptions.bsvi"
`undef CHERIException
default: $format("cheriExcUnknown");
endcase);
endfunction
endinstance
typedef struct {
Bit #(6) cheri_exc_reg;
CHERIException cheri_exc_code;
} CSR_XCapCause deriving(Bits, Eq, FShow);
CSR_XCapCause noCapCause = CSR_XCapCause {cheri_exc_code: cheriExcNone,
cheri_exc_reg: unpack(0)};
// SCR map
typedef struct { Bit#(5) addr; } SCR deriving(Bits, Eq);
`define SCR(n, v) SCR scrAddr``n = SCR { addr: v };
`include "SCRs.bsvi"
// As with CSRs, SCR that catches all unimplemented SCRs
`SCR(None, 5'd10)
`undef SCR
instance FShow#(SCR);
function Fmt fshow(SCR scr);
return (case(scr.addr)
`define SCR(n, v) v: $format(`"``scrAddr``n```");
`include "SCRs.bsvi"
`undef SCR
default: $format("scrAddrNone");
endcase);
endfunction
endinstance
function SCR unpackSCR(Bit#(5) addr);
return (case(addr)
`define SCR(n, v) v: scrAddr``n;
`include "SCRs.bsvi"
`undef SCR
default: scrAddrNone;
endcase);
endfunction
function CapPipe update_scr_via_csr (CapPipe old_scr, WordXL new_csr, Bool allow_sealed);
let new_scr = setAddr(old_scr, new_csr);
let ret = new_scr.value;
if (!new_scr.exact || (getKind(old_scr) != UNSEALED && !allow_sealed)) begin
ret = setValidCap(ret, False);
end
return ret;
endfunction
RegName cCallRD = 31;
// Instruction field encodings
// Top-level opcodes
Opcode op_cap_Manip = 7'h5b;
//Opcode op_cap_Mem = 7'h0b; // Not yet implemented
// ================================================================
// op_cap_Manip opcode subdivision
// f3 selects between immediate and 3-reg instructions
Bit #(3) f3_cap_ThreeOp = 3'h0;
Bit #(3) f3_cap_CIncOffsetImmediate = 3'h1;
Bit #(3) f3_cap_CSetBoundsImmediate = 3'h2;
// 3'h3-3'h7 unused
// ================================================================
// op_cap_ThreeOp opcode subdivision
// f7 selects between 3-reg operations
// 7'h00 unused
Bit #(7) f7_cap_CSpecialRW = 7'h01;
// 7'h02-7'h07 unused
Bit #(7) f7_cap_CSetBounds = 7'h08;
Bit #(7) f7_cap_CSetBoundsExact = 7'h09;
// 7'h0a unused
Bit #(7) f7_cap_CSeal = 7'h0b;
Bit #(7) f7_cap_CUnseal = 7'h0c;
Bit #(7) f7_cap_CAndPerm = 7'h0d;
Bit #(7) f7_cap_CSetFlags = 7'h0e;
Bit #(7) f7_cap_CSetOffset = 7'h0f;
Bit #(7) f7_cap_CSetAddr = 7'h10;
Bit #(7) f7_cap_CIncOffset = 7'h11;
Bit #(7) f7_cap_CToPtr = 7'h12;
Bit #(7) f7_cap_CFromPtr = 7'h13;
Bit #(7) f7_cap_CSub = 7'h14;
// 7'h15 unused
Bit #(7) f7_cap_CSetHigh = 7'h16;
// 7'h17-7'h1c unused
Bit #(7) f7_cap_CBuildCap = 7'h1d;
Bit #(7) f7_cap_CCopyType = 7'h1e;
Bit #(7) f7_cap_CCSeal = 7'h1f;
Bit #(7) f7_cap_CTestSubset = 7'h20;
Bit #(7) f7_cap_CSetEqualExact = 7'h21;
// 7'h22-7'hfb unused
Bit #(7) f7_cap_Stores = 7'h7c;
Bit #(7) f7_cap_Loads = 7'h7d;
Bit #(7) f7_cap_TwoSrc = 7'h7e;
Bit #(7) f7_cap_TwoOp = 7'h7f;
// ================================================================
// f7_cap_TwoSrc opcode subdivision
// rd selects between 2-reg operations
// 5'h00 unused
Bit #(5) rd_cap_CCall = 5'h01;
// 5'h02-5'h1f unused
// ================================================================
// f7_cap_TwoOp opcode subdivision
// f5rs2 selects between 2-reg operations (f5rs2 instead of f5 because f5
// is already used in RISC-V and is in a different position
Bit #(5) f5rs2_cap_CGetPerm = 5'h00;
Bit #(5) f5rs2_cap_CGetType = 5'h01;
Bit #(5) f5rs2_cap_CGetBase = 5'h02;
Bit #(5) f5rs2_cap_CGetLen = 5'h03;
Bit #(5) f5rs2_cap_CGetTag = 5'h04;
Bit #(5) f5rs2_cap_CGetSealed = 5'h05;
Bit #(5) f5rs2_cap_CGetOffset = 5'h06;
Bit #(5) f5rs2_cap_CGetFlags = 5'h07;
Bit #(5) f5rs2_cap_CRRL = 5'h08;
Bit #(5) f5rs2_cap_CRAM = 5'h09;
Bit #(5) f5rs2_cap_CMove = 5'h0a;
Bit #(5) f5rs2_cap_CClearTag = 5'h0b;
Bit #(5) f5rs2_cap_JALR_CAP = 5'h0c;
Bit #(5) f5rs2_cap_CClearReg = 5'h0d;
// 5'h0e unused
Bit #(5) f5rs2_cap_CGetAddr = 5'h0f;
Bit #(5) f5rs2_cap_CClearFPReg = 5'h10;
Bit #(5) f5rs2_cap_CSealEntry = 5'h11;
Bit #(5) f5rs2_cap_CLoadTags = 5'h12;
// 5'h13 unused
Bit #(5) f5rs2_cap_JALR_PCC = 5'h14;
// 5'h15-5'h16 unused
Bit #(5) f5rs2_cap_CGetHigh = 5'h17;
// 5'h18-5'h1f unused (5'h1f reserved for 1-reg instructions)
// ================================================================
// f7_cap_{Load, Store} opcode subdivision
MemReqSize cap_mem_SIZE_B = 'h0;
MemReqSize cap_mem_SIZE_H = 'h1;
MemReqSize cap_mem_SIZE_W = 'h2;
MemReqSize cap_mem_SIZE_D = 'h3;
//MemReqSize f5rs2_cap_mem_SIZE_Q = 'h4; //TODO
Bit #(1) cap_mem_ddc = 1'h0;
Bit #(1) cap_mem_cap = 1'h1;
Bit #(1) cap_mem_unsigned = 1'h1;
Bit #(1) cap_mem_signed = 1'h0;
// ================================================================
// Other:
// Region in MISC_MEM for LQ
Bit #(3) f3_LQ = 3'h2;
Bit #(3) f3_SQ = 3'b100;
`ifdef RV64
Bit #(3) w_SIZE_CAP = f3_SQ;
Bit #(3) w_SIZE_MAX = f3_SQ;
`else //RV32
Bit #(3) w_SIZE_CAP = f3_SD;
Bit #(3) w_SIZE_MAX = f3_SD;
`endif
Bit #(3) f3_AMO_CAP = w_SIZE_CAP;
// Special cases of Otypes that are extended to XLEN
Bit #(XLEN) otype_unsealed_ext = -1;
Bit #(XLEN) otype_sentry_ext = -2;
Bit #(XLEN) otype_res0_ext = -3;
Bit #(XLEN) otype_res1_ext = -4;