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//===- LanaiInstrFormats.td - Lanai Instruction Formats ----*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
class InstLanai<dag outs, dag ins, string asmstr, list<dag> pattern>
: Instruction {
field bits<32> Inst;
field bits<32> SoftFail = 0;
let Size = 4;
let Namespace = "Lanai";
let DecoderNamespace = "Lanai";
bits<4> Opcode;
let Inst{31 - 28} = Opcode;
dag OutOperandList = outs;
dag InOperandList = ins;
let AsmString = asmstr;
let Pattern = pattern;
}
//------------------------------------------------------------------------------
// Register Immediate (RI)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |0.A.A.A| . . . . | . . . . |F.H| . . . . . . . . . . . . . . . |
// -----------------------------------------------------------------
// opcode Rd Rs1 constant (16)
//
// Action:
// Rd <- Rs1 op constant
//
// Except for shift instructions, `H' determines whether the constant
// is in the high (1) or low (0) word. The other halfword is 0x0000,
// except for the `AND' instruction (`AAA' = 100), for which the other
// halfword is 0xFFFF, and shifts (`AAA' = 111), for which the constant is
// sign extended.
//
// `F' determines whether the instruction modifies (1) or does not
// modify (0) the program flags.
//
// `AAA' specifies the operation: `add' (000), `addc' (001), `sub'
// (010), `subb' (011), `and' (100), `or' (101), `xor' (110), or `shift'
// (111). For the shift, `H' specifies a logical (0) or arithmetic (1)
// shift. The amount and direction of the shift are determined by the
// sign extended constant interpreted as a two's complement number. The
// shift operation is defined only for the range of:
// 31 ... 0 -1 ... -31
// \ / \ /
// left right
// shift shift
//
// If and only if the `F' bit is 1, RI instructions modify the
// condition bits, `Z' (Zero), `N' (Negative), `V' (oVerflow), and `C'
// (Carry), according to the result. If the flags are updated, they are
// updated as follows:
// `Z'
// is set if the result is zero and cleared otherwise.
//
// `N'
// is set to the most significant bit of the result.
//
// `V'
// For arithmetic instructions (`add', `addc', `sub', `subb') `V' is
// set if the sign (most significant) bits of the input operands are
// the same but different from the sign bit of the result and cleared
// otherwise. For other RI instructions, `V' is cleared.
//
// `C'
// For arithmetic instructions, `C' is set/cleared if there is/is_not
// a carry generated out of the most significant when performing the
// twos-complement addition (`sub(a,b) == a + ~b + 1', `subb(a,b) ==
// a + ~b + `C''). For left shifts, `C' is set to the least
// significant bit discarded by the shift operation. For all other
// operations, `C' is cleared.
//
// A Jump is accomplished by `Rd' being `pc', and it has one shadow.
//
// The all-0s word is the instruction `R0 <- R0 + 0', which is a no-op.
class InstRI<bits<3> op, dag outs, dag ins, string asmstr,
list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern>, Sched<[WriteALU]> {
let Itinerary = IIC_ALU;
bits<5> Rd;
bits<5> Rs1;
bit F;
bit H;
bits<16> imm16;
let Opcode{3} = 0;
let Opcode{2 - 0} = op;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = Rs1;
let Inst{17} = F;
let Inst{16} = H;
let Inst{15 - 0} = imm16;
}
//------------------------------------------------------------------------------
// Register Register (RR)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.0.0| . . . . | . . . . |F.I| . . . . |B.B.B|J.J.J.J.J|D.D.D|
// -----------------------------------------------------------------
// opcode Rd Rs1 Rs2 \ operation /
//
// Action:
// `Rd <- Rs1 op Rs2' iff condition DDDI is true.
//
// `DDDI' is as described for the BR instruction.
//
// `F' determines whether the instruction modifies (1) or does not
// modify (0) the program flags.
//
// `BBB' determines the operation: `add' (000), `addc' (001), `sub'
// (010), `subb' (011), `and' (100), `or' (101), `xor' (110), or "special"
// (111). The `JJJJJ' field is irrelevant except for special.
//
// `JJJJJ' determines which special operation is performed. `10---'
// is a logical shift, and `11---' is an arithmetic shift, and ‘00000` is
// the SELECT operation. The amount and direction of the shift are
// determined by the contents of `Rs2' interpreted as a two's complement
// number (in the same way as shifts in the Register-Immediate
// instructions in *Note RI::). For the SELECT operation, Rd gets Rs1 if
// condition DDDI is true, Rs2 otherwise. All other `JJJJJ' combinations
// are reserved for instructions that may be defined in the future.
//
// If the `F' bit is 1, RR instructions modify the condition bits, `Z'
// (Zero), `N' (Negative), `V' (oVerflow), and `C' (Carry), according to
// the result. All RR instructions modify the `Z', `N', and `V' flags.
// Except for arithmetic instructions (`add', `addc', `sub', `subb'), `V'
// is cleared. Only arithmetic instructions and shifts modify `C'. Right
// shifts clear C.
//
// DDDI is as described in the table for the BR instruction and only used for
// the select instruction.
//
// A Jump is accomplished by `Rd' being `pc', and it has one shadow.
class InstRR<bits<3> op, dag outs, dag ins, string asmstr,
list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern>, Sched<[WriteALU]> {
let Itinerary = IIC_ALU;
bits<5> Rd;
bits<5> Rs1;
bits<5> Rs2;
bit F;
bits<4> DDDI;
bits<5> JJJJJ;
let Opcode = 0b1100;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = Rs1;
let Inst{17} = F;
let Inst{16} = DDDI{0};
let Inst{15 - 11} = Rs2;
let Inst{10 - 8} = op;
let Inst{7 - 3} = JJJJJ;
let Inst{2 - 0} = DDDI{3 - 1};
}
//------------------------------------------------------------------------------
// Register Memory (RM)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.0.0.S| . . . . | . . . . |P.Q| . . . . . . . . . . . . . . . |
// -----------------------------------------------------------------
// opcode Rd Rs1 constant (16)
//
// Action:
// Rd <- Memory(ea) (Load) see below for the
// Memory(ea) <- Rd (Store) definition of ea.
//
// `S' determines whether the instruction is a Load (0) or a Store (1).
// Loads appear in Rd one cycle after this instruction executes. If the
// following instruction reads Rd, that instruction will be delayed by 1
// clock cycle.
//
// PQ operation
// -- ------------------------------------------
// 00 ea = Rs1
// 01 ea = Rs1, Rs1 <- Rs1 + constant
// 10 ea = Rs1 + constant
// 11 ea = Rs1 + constant, Rs1 <- Rs1 + constant
//
// The constant is sign-extended for this instruction.
//
// A Jump is accomplished by `Rd' being `pc', and it has *two* delay slots.
class InstRM<bit S, dag outs, dag ins, string asmstr, list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
bits<5> Rd;
bits<5> Rs1;
bit P;
bit Q;
bits<16> imm16;
// Dummy variables to allow multiclass definition of RM and RRM
bits<2> YL;
bit E;
let Opcode{3 - 1} = 0b100;
let Opcode{0} = S;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = Rs1;
let Inst{17} = P;
let Inst{16} = Q;
let Inst{15 - 0} = imm16;
let PostEncoderMethod = "adjustPqBitsRmAndRrm";
}
//------------------------------------------------------------------------------
// Register Register Memory (RRM)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.0.1.S| . . . . | . . . . |P.Q| . . . . |B.B.B|J.J.J.J.J|Y.L.E|
// -----------------------------------------------------------------
// opcode Rd Rs1 Rs2 \ operation /
//
// Action:
// Rd <- Memory(ea) (Load) see below for the
// Memory(ea) <- Rd (Store) definition of ea.
//
// The RRM instruction is identical to the RM (*note RM::.) instruction
// except that:
//
// 1. `Rs1 + constant' is replaced with `Rs1 op Rs2', where `op' is
// determined in the same way as in the RR instruction (*note RR::.)
// and
//
// 2. part-word memory accesses are allowed as specified below.
//
// If `BBB' != 111 (i.e.: For all but shift operations):
// If `YLE' = 01- => fuLl-word memory access
// If `YLE' = 00- => half-word memory access
// If `YLE' = 10- => bYte memory access
// If `YLE' = --1 => loads are zEro extended
// If `YLE' = --0 => loads are sign extended
//
// If `BBB' = 111 (For shift operations):
// fullword memory access are performed.
//
// All part-word loads write the least significant part of the
// destination register with the higher-order bits zero- or sign-extended.
// All part-word stores store the least significant part-word of the
// source register in the destination memory location.
//
// A Jump is accomplished by `Rd' being `pc', and it has *two* delay slots.
class InstRRM<bit S, dag outs, dag ins, string asmstr,
list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
bits<5> Rd;
bits<5> Rs1;
bits<5> Rs2;
bit P;
bit Q;
bits<3> BBB;
bits<5> JJJJJ;
bits<2> YL;
bit E;
let Opcode{3 - 1} = 0b101;
let Opcode{0} = S;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = Rs1;
let Inst{17} = P;
let Inst{16} = Q;
let Inst{15 - 11} = Rs2;
let Inst{10 - 8} = BBB;
let Inst{7 - 3} = JJJJJ;
let Inst{2 - 1} = YL;
let Inst{0} = E;
let PostEncoderMethod = "adjustPqBitsRmAndRrm";
}
//------------------------------------------------------------------------------
// Conditional Branch (BR)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.1.0|D.D.D| . . . . . . . . . . . . . . . . . . . . . . |0.I|
// -----------------------------------------------------------------
// opcode condition constant (23)
//
// Action:
// if (condition) { `pc' <- 4*(zero-extended constant) }
//
// The BR instruction is an absolute branch.
// The constant is scaled as shown by its position in the instruction word such
// that it specifies word-aligned addresses in the range [0,2^25-4]
//
// The `DDDI' field selects the condition that causes the branch to be taken.
// (the `I' (Invert sense) bit inverts the sense of the condition):
//
// DDDI logical function [code, used for...]
// ---- -------------------------------------- ------------------------
// 0000 1 [T, true]
// 0001 0 [F, false]
// 0010 C AND Z' [HI, high]
// 0011 C' OR Z [LS, low or same]
// 0100 C' [CC, carry cleared]
// 0101 C [CS, carry set]
// 0110 Z' [NE, not equal]
// 0111 Z [EQ, equal]
// 1000 V' [VC, oVerflow cleared]
// 1001 V [VS, oVerflow set]
// 1010 N' [PL, plus]
// 1011 N [MI, minus]
// 1100 (N AND V) OR (N' AND V') [GE, greater than or equal]
// 1101 (N AND V') OR (N' AND V) [LT, less than]
// 1110 (N AND V AND Z') OR (N' AND V' AND Z') [GT, greater than]
// 1111 (Z) OR (N AND V') OR (N' AND V) [LE, less than or equal]
//
// If the branch is not taken, the BR instruction is a no-op. If the branch is
// taken, the processor starts executing instructions at the branch target
// address *after* the processor has executed one more instruction. That is,
// the branch has one “branch delay slot”. Be very careful if you find yourself
// wanting to put a branch in a branch delays slot!
class InstBR<dag outs, dag ins, string asmstr, list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
let Itinerary = IIC_ALU;
bits<25> addr;
bits<4> DDDI;
let Opcode = 0b1110;
let Inst{27 - 25} = DDDI{3 - 1};
let Inst{24 - 0} = addr;
// These instructions overwrite the last two address bits (which are assumed
// and ensured to be 0).
let Inst{1} = 0;
let Inst{0} = DDDI{0};
}
//------------------------------------------------------------------------------
// Conditional Branch Relative (BRR)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.1.0|D.D.D|1|-| . . . . |-.-| . . . . . . . . . . . . . |1.I|
// -----------------------------------------------------------------
// opcode condition Rs1 constant (14)
// Action:
// if (condition) { ‘pc’ <- Rs1 + 4*sign-extended constant) }
//
// BRR behaves like BR, except the branch target address is a 16-bit PC relative
// offset.
class InstBRR<dag outs, dag ins, string asmstr, list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
bits<4> DDDI;
bits<5> Rs1;
bits<16> imm16;
let Opcode = 0b1110;
let Inst{27 - 25} = DDDI{3 - 1};
let Inst{24} = 1;
let Inst{22 - 18} = Rs1;
let Inst{17 - 16} = 0;
let Inst{15 - 0} = imm16;
// Overwrite last two bits which have to be zero
let Inst{1} = 1;
let Inst{0} = DDDI{0};
// Set don't cares to zero
let Inst{23} = 0;
}
//------------------------------------------------------------------------------
// Conditional Set (SCC)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.1.0|D.D.D|0.-| . . . . |-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-|1.I|
// -----------------------------------------------------------------
// opcode condition Rs1
//
// Action:
// Rs1 <- logical function result
//
// SCC sets dst_reg to the boolean result of computing the logical function
// specified by DDDI, as described in the table for the BR instruction.
class InstSCC<dag outs, dag ins, string asmstr,
list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
let Itinerary = IIC_ALU;
bits<5> Rs1; // dst_reg in documentation
bits<4> DDDI;
let Opcode = 0b1110;
let Inst{27 - 25} = DDDI{3 - 1};
let Inst{24} = 0;
let Inst{22 - 18} = Rs1;
let Inst{1} = 1;
let Inst{0} = DDDI{0};
// Set don't cares to zero
let Inst{23} = 0;
let Inst{17 - 2} = 0;
}
//------------------------------------------------------------------------------
// Special Load/Store (SLS)
//------------------------------------------------------------------------------
//
// Encoding:
// -----------------------------------------------------------------
// |1.1.1.1| . . . . | . . . . |0.S| . . . . . . . . . . . . . . . |
// -----------------------------------------------------------------
// opcode Rd addr 5msb's address 16 lsb's
//
// Action:
// If S = 0 (LOAD): Rd <- Memory(address);
// If S = 1 (STORE): Memory(address) <- Rd
//
// The timing is the same as for RM (*note RM::.) and RRM (*note
// RRM::.) instructions. The two low-order bits of the 21-bit address are
// ignored. The address is zero extended. Fullword memory accesses are
// performed.
class InstSLS<bit S, dag outs, dag ins, string asmstr, list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
bits<5> Rd;
bits<5> msb;
bits<16> lsb;
let Opcode = 0b1111;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = msb;
let Inst{17} = 0;
let Inst{16} = S;
let Inst{15 - 0} = lsb;
}
//------------------------------------------------------------------------------
// Special Load Immediate (SLI)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.1.1| . . . . | . . . . |1.0| . . . . . . . . . . . . . . . |
// -----------------------------------------------------------------
// opcode Rd const 5msb's constant 16 lsb's
//
// Action:
// Rd <- constant
//
// The 21-bit constant is zero-extended. The timing is the same as the
// RM instruction (*note RM::.).
class InstSLI<dag outs, dag ins, string asmstr, list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
bits<5> Rd;
bits<5> msb;
bits<16> lsb;
let Opcode = 0b1111;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = msb;
let Inst{17} = 1;
let Inst{16} = 0;
let Inst{15 - 0} = lsb;
}
//------------------------------------------------------------------------------
// Special Part-Word Load/Store (SPLS)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.1.1| . . . . | . . . . |1.1.0.Y.S.E.P.Q| . . . . . . . . . |
// -----------------------------------------------------------------
// opcode Rd Rs1 constant (10)
//
// Action:
// If `YS' = 11 (bYte Store):
// Memory(ea) <- (least significant byte of Rr)
// If `YS' = 01 (halfword Store):
// Memory(ea) <- (least significant half-word of Rr)
// If `YS' = 10 (bYte load): Rr <- Memory(ea)
// If `YS' = 00 (halfword load): Rr <- Memory(ea)
// [Note: here ea is determined as in the RM instruction. ]
// If `SE' = 01 then the value is zEro extended
// before being loaded into Rd.
// If `SE' = 00 then the value is sign extended
// before being loaded into Rd.
//
// `P' and `Q' are used to determine `ea' as in the RM instruction. The
// constant is sign extended. The timing is the same as the RM and RRM
// instructions. *Note RM:: and *Note RRM::.
//
// All part-word loads write the part-word into the least significant
// part of the destination register, with the higher-order bits zero- or
// sign-extended. All part-word stores store the least significant
// part-word of the source register into the destination memory location.
class InstSPLS<dag outs, dag ins, string asmstr,
list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
bits<5> Rd;
bits<5> Rs1;
bits<5> msb;
bit Y;
bit S;
bit E;
bit P;
bit Q;
bits<10> imm10;
let Opcode = 0b1111;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = Rs1;
let Inst{17 - 15} = 0b110;
let Inst{14} = Y;
let Inst{13} = S;
let Inst{12} = E;
let Inst{11} = P;
let Inst{10} = Q;
let Inst{9 - 0} = imm10;
let PostEncoderMethod = "adjustPqBitsSpls";
}
//------------------------------------------------------------------------------
// Special instructions (popc, leadz, trailz)
//------------------------------------------------------------------------------
// Encoding:
// -----------------------------------------------------------------
// |1.1.0.1| Rd | Rs1 |F.-| . . . . | . . | . . . . | OP |
// -----------------------------------------------------------------
// opcode Rd Rs1
// Action:
// Rd <- Perform action encoded in OP on Rs1
// OP is one of:
// 0b001 POPC Population count;
// 0b010 LEADZ Count number of leading zeros;
// 0b011 TRAILZ Count number of trailing zeros;
class InstSpecial<bits<3> op, dag outs, dag ins, string asmstr,
list<dag> pattern> : InstLanai<outs, ins, asmstr,
pattern>, Sched<[WriteALU]> {
let Itinerary = IIC_ALU;
bit F;
bits<5> Rd;
bits<5> Rs1;
let Opcode = 0b1101;
let Inst{27 - 23} = Rd;
let Inst{22 - 18} = Rs1;
let Inst{17} = F;
let Inst{16 - 3} = 0;
let Inst{2 - 0} = op;
}
// Pseudo instructions
class Pseudo<dag outs, dag ins, string asmstr, list<dag> pattern>
: InstLanai<outs, ins, asmstr, pattern> {
let Inst{15 - 0} = 0;
let isPseudo = 1;
}