execute1: Remember dest GPR, RC, OE, XER for slow operations

For multiply and divide operations, execute1 now records the
destination GPR number, RC and OE from the instruction, and the
XER value.  This means that the multiply and divide units don't
need to record those values and then send them back to execute1.
This makes the interface to those units a bit simpler.  They
simply report an overflow signal along with the result value, and
execute1 takes care of updating XER if necessary.

Signed-off-by: Paul Mackerras <paulus@ozlabs.org>
jtag-port
Paul Mackerras 5 years ago
parent 39d18d2738
commit c9a2076dd3

@ -133,21 +133,16 @@ package common is
type Execute1ToMultiplyType is record
valid: std_ulogic;
insn_type: insn_type_t;
write_reg: gpr_index_t;
data1: std_ulogic_vector(64 downto 0);
data2: std_ulogic_vector(64 downto 0);
rc: std_ulogic;
oe: std_ulogic;
is_32bit: std_ulogic;
xerc: xer_common_t;
end record;
constant Execute1ToMultiplyInit : Execute1ToMultiplyType := (valid => '0', insn_type => OP_ILLEGAL, rc => '0',
oe => '0', is_32bit => '0', xerc => xerc_init,
constant Execute1ToMultiplyInit : Execute1ToMultiplyType := (valid => '0', insn_type => OP_ILLEGAL,
is_32bit => '0',
others => (others => '0'));

type Execute1ToDividerType is record
valid: std_ulogic;
write_reg: gpr_index_t;
dividend: std_ulogic_vector(63 downto 0);
divisor: std_ulogic_vector(63 downto 0);
is_signed: std_ulogic;
@ -155,13 +150,9 @@ package common is
is_extended: std_ulogic;
is_modulus: std_ulogic;
neg_result: std_ulogic;
rc: std_ulogic;
oe: std_ulogic;
xerc: xer_common_t;
end record;
constant Execute1ToDividerInit: Execute1ToDividerType := (valid => '0', is_signed => '0', is_32bit => '0',
is_extended => '0', is_modulus => '0',
rc => '0', oe => '0', xerc => xerc_init,
neg_result => '0', others => (others => '0'));

type Decode2ToRegisterFileType is record
@ -264,30 +255,18 @@ package common is

type MultiplyToExecute1Type is record
valid: std_ulogic;

write_reg_nr: gpr_index_t;
write_reg_data: std_ulogic_vector(63 downto 0);
write_xerc_enable : std_ulogic;
xerc : xer_common_t;
rc: std_ulogic;
overflow : std_ulogic;
end record;
constant MultiplyToExecute1Init : MultiplyToExecute1Type := (valid => '0',
rc => '0', write_xerc_enable => '0',
xerc => xerc_init,
constant MultiplyToExecute1Init : MultiplyToExecute1Type := (valid => '0', overflow => '0',
others => (others => '0'));

type DividerToExecute1Type is record
valid: std_ulogic;

write_reg_nr: gpr_index_t;
write_reg_data: std_ulogic_vector(63 downto 0);
write_xerc_enable : std_ulogic;
xerc : xer_common_t;
rc: std_ulogic;
overflow : std_ulogic;
end record;
constant DividerToExecute1Init : DividerToExecute1Type := (valid => '0',
rc => '0', write_xerc_enable => '0',
xerc => xerc_init,
constant DividerToExecute1Init : DividerToExecute1Type := (valid => '0', overflow => '0',
others => (others => '0'));

type WritebackToRegisterFileType is record

@ -300,7 +300,9 @@ begin
v.e.read_data3 := decoded_reg_c.data;
v.e.write_reg := decoded_reg_o.reg;
v.e.rc := decode_rc(d_in.decode.rc, d_in.insn);
if not (d_in.decode.insn_type = OP_MUL_H32 or d_in.decode.insn_type = OP_MUL_H64) then
v.e.oe := decode_oe(d_in.decode.rc, d_in.insn);
end if;
v.e.cr := c_in.read_cr_data;
v.e.xerc := c_in.read_xerc_data;
v.e.invert_a := d_in.decode.invert_a;

@ -29,13 +29,9 @@ architecture behaviour of divider is
signal is_32bit : std_ulogic;
signal extended : std_ulogic;
signal is_signed : std_ulogic;
signal rc : std_ulogic;
signal write_reg : std_ulogic_vector(4 downto 0);
signal overflow : std_ulogic;
signal ovf32 : std_ulogic;
signal did_ovf : std_ulogic;
signal oe : std_ulogic;
signal xerc : xer_common_t;
begin
divider_0: process(clk)
begin
@ -54,15 +50,11 @@ begin
end if;
div <= unsigned(d_in.divisor);
quot <= (others => '0');
write_reg <= d_in.write_reg;
neg_result <= d_in.neg_result;
is_modulus <= d_in.is_modulus;
extended <= d_in.is_extended;
is_32bit <= d_in.is_32bit;
is_signed <= d_in.is_signed;
rc <= d_in.rc;
oe <= d_in.oe;
xerc <= d_in.xerc;
count <= "1111111";
running <= '1';
overflow <= '0';
@ -98,9 +90,6 @@ begin

divider_1: process(all)
begin
d_out.write_reg_nr <= write_reg;
d_out.rc <= rc;

if is_modulus = '1' then
result <= dend(128 downto 65);
else
@ -136,21 +125,9 @@ begin
if rising_edge(clk) then
d_out.valid <= '0';
d_out.write_reg_data <= oresult;
d_out.write_xerc_enable <= '0';
d_out.xerc <= xerc;
d_out.overflow <= did_ovf;
if count = "1000000" then
d_out.valid <= '1';
d_out.write_xerc_enable <= oe;

-- We must test oe because the RC update code in writeback
-- will use the xerc value to set CR0:SO so we must not clobber
-- xerc if OE wasn't set.
--
if oe = '1' then
d_out.xerc.ov <= did_ovf;
d_out.xerc.ov32 <= did_ovf;
d_out.xerc.so <= xerc.so or did_ovf;
end if;
end if;
end if;
end process;

@ -43,7 +43,6 @@ begin
rst <= '0';

d1.valid <= '1';
d1.write_reg <= "10001";
d1.dividend <= x"0000000010001000";
d1.divisor <= x"0000000000001111";
d1.is_signed <= '0';
@ -51,7 +50,6 @@ begin
d1.is_extended <= '0';
d1.is_modulus <= '0';
d1.neg_result <= '0';
d1.rc <= '0';

wait for clk_period;
assert d2.valid = '0';
@ -66,15 +64,12 @@ begin
end loop;

assert d2.valid = '1';
assert d2.write_reg_nr = "10001";
assert d2.write_reg_data = x"000000000000f001" report "result " & to_hstring(d2.write_reg_data);
assert d2.rc = '0';

wait for clk_period;
assert d2.valid = '0' report "valid";

d1.valid <= '1';
d1.rc <= '1';

wait for clk_period;
assert d2.valid = '0' report "valid";
@ -89,9 +84,7 @@ begin
end loop;

assert d2.valid = '1';
assert d2.write_reg_nr = "10001";
assert d2.write_reg_data = x"000000000000f001" report "result " & to_hstring(d2.write_reg_data);
assert d2.rc = '1';

wait for clk_period;
assert d2.valid = '0';

@ -38,6 +38,10 @@ architecture behaviour of execute1 is
next_lr : std_ulogic_vector(63 downto 0);
mul_in_progress : std_ulogic;
div_in_progress : std_ulogic;
slow_op_dest : gpr_index_t;
slow_op_rc : std_ulogic;
slow_op_oe : std_ulogic;
slow_op_xerc : xer_common_t;
end record;

signal r, rin : reg_type;
@ -187,6 +191,7 @@ begin
variable carry_32, carry_64 : std_ulogic;
variable sign1, sign2 : std_ulogic;
variable abs1, abs2 : signed(63 downto 0);
variable overflow : std_ulogic;
begin
result := (others => '0');
result_with_carry := (others => '0');
@ -238,12 +243,6 @@ begin
-- signals to multiply unit
x_to_multiply <= Execute1ToMultiplyInit;
x_to_multiply.insn_type <= e_in.insn_type;
x_to_multiply.write_reg <= gspr_to_gpr(e_in.write_reg);
x_to_multiply.rc <= e_in.rc;
x_to_multiply.xerc <= v.e.xerc;
if e_in.insn_type = OP_MUL_L64 then
x_to_multiply.oe <= e_in.oe;
end if;
x_to_multiply.is_32bit <= e_in.is_32bit;

if e_in.is_32bit = '1' then
@ -291,16 +290,12 @@ begin
end if;

x_to_divider <= Execute1ToDividerInit;
x_to_divider.write_reg <= gspr_to_gpr(e_in.write_reg);
x_to_divider.is_signed <= e_in.is_signed;
x_to_divider.is_32bit <= e_in.is_32bit;
if e_in.insn_type = OP_MOD then
x_to_divider.is_modulus <= '1';
end if;
x_to_divider.neg_result <= sign1 xor (sign2 and not x_to_divider.is_modulus);
x_to_divider.rc <= e_in.rc;
x_to_divider.oe <= e_in.oe;
x_to_divider.xerc <= v.e.xerc;
if e_in.is_32bit = '0' then
-- 64-bit forms
if e_in.insn_type = OP_DIVE then
@ -342,6 +337,10 @@ begin
v.e.write_reg := e_in.write_reg;
v.e.write_len := x"8";
v.e.sign_extend := '0';
v.slow_op_dest := gspr_to_gpr(e_in.write_reg);
v.slow_op_rc := e_in.rc;
v.slow_op_oe := e_in.oe;
v.slow_op_xerc := v.e.xerc;

case_0: case e_in.insn_type is

@ -664,35 +663,36 @@ begin
v.e.write_len := x"8";
v.e.sign_extend := '0';
v.e.valid := '1';
elsif r.mul_in_progress = '1' then
if multiply_to_x.valid = '1' then
v.e.write_reg := gpr_to_gspr(multiply_to_x.write_reg_nr);
elsif r.mul_in_progress = '1' or r.div_in_progress = '1' then
if (r.mul_in_progress = '1' and multiply_to_x.valid = '1') or
(r.div_in_progress = '1' and divider_to_x.valid = '1') then
if r.mul_in_progress = '1' then
result := multiply_to_x.write_reg_data;
result_en := '1';
v.e.rc := multiply_to_x.rc;
v.e.xerc := multiply_to_x.xerc;
v.e.write_xerc_enable := multiply_to_x.write_xerc_enable;
v.e.valid := '1';
v.e.write_len := x"8";
v.e.sign_extend := '0';
overflow := multiply_to_x.overflow;
else
stall_out <= '1';
v.mul_in_progress := '1';
end if;
elsif r.div_in_progress = '1' then
if divider_to_x.valid = '1' then
v.e.write_reg := gpr_to_gspr(divider_to_x.write_reg_nr);
result := divider_to_x.write_reg_data;
overflow := divider_to_x.overflow;
end if;
result_en := '1';
v.e.rc := divider_to_x.rc;
v.e.xerc := divider_to_x.xerc;
v.e.write_xerc_enable := divider_to_x.write_xerc_enable;
v.e.write_reg := gpr_to_gspr(v.slow_op_dest);
v.e.rc := v.slow_op_rc;
v.e.xerc := v.slow_op_xerc;
v.e.write_xerc_enable := v.slow_op_oe;
-- We must test oe because the RC update code in writeback
-- will use the xerc value to set CR0:SO so we must not clobber
-- xerc if OE wasn't set.
if v.slow_op_oe = '1' then
v.e.xerc.ov := overflow;
v.e.xerc.ov32 := overflow;
v.e.xerc.so := v.slow_op_xerc.so or overflow;
end if;
v.e.valid := '1';
v.e.write_len := x"8";
v.e.sign_extend := '0';
else
stall_out <= '1';
v.div_in_progress := '1';
v.mul_in_progress := r.mul_in_progress;
v.div_in_progress := r.div_in_progress;
end if;
end if;


@ -25,19 +25,12 @@ architecture behaviour of multiply is
valid : std_ulogic;
insn_type : insn_type_t;
data : signed(129 downto 0);
write_reg : std_ulogic_vector(4 downto 0);
rc : std_ulogic;
oe : std_ulogic;
is_32bit : std_ulogic;
xerc : xer_common_t;
end record;
constant MultiplyPipelineStageInit : multiply_pipeline_stage := (valid => '0',
insn_type => OP_ILLEGAL,
rc => '0', oe => '0',
is_32bit => '0',
xerc => xerc_init,
data => (others => '0'),
others => (others => '0'));
data => (others => '0'));

type multiply_pipeline_type is array(0 to PIPELINE_DEPTH-1) of multiply_pipeline_stage;
constant MultiplyPipelineInit : multiply_pipeline_type := (others => MultiplyPipelineStageInit);
@ -69,11 +62,7 @@ begin
v.multiply_pipeline(0).valid := m.valid;
v.multiply_pipeline(0).insn_type := m.insn_type;
v.multiply_pipeline(0).data := signed(m.data1) * signed(m.data2);
v.multiply_pipeline(0).write_reg := m.write_reg;
v.multiply_pipeline(0).rc := m.rc;
v.multiply_pipeline(0).oe := m.oe;
v.multiply_pipeline(0).is_32bit := m.is_32bit;
v.multiply_pipeline(0).xerc := m.xerc;

loop_0: for i in 1 to PIPELINE_DEPTH-1 loop
v.multiply_pipeline(i) := r.multiply_pipeline(i-1);
@ -101,24 +90,10 @@ begin
end case;

m_out.write_reg_data <= d2;
m_out.write_reg_nr <= v.multiply_pipeline(PIPELINE_DEPTH-1).write_reg;
m_out.xerc <= v.multiply_pipeline(PIPELINE_DEPTH-1).xerc;
m_out.overflow <= ov;

-- Generate OV/OV32/SO when OE=1
if v.multiply_pipeline(PIPELINE_DEPTH-1).valid = '1' then
m_out.valid <= '1';
m_out.rc <= v.multiply_pipeline(PIPELINE_DEPTH-1).rc;
m_out.write_xerc_enable <= v.multiply_pipeline(PIPELINE_DEPTH-1).oe;

-- We must test oe because the RC update code in writeback
-- will use the xerc value to set CR0:SO so we must not clobber
-- xerc if OE wasn't set.
--
if v.multiply_pipeline(PIPELINE_DEPTH-1).oe = '1' then
m_out.xerc.ov <= ov;
m_out.xerc.ov32 <= ov;
m_out.xerc.so <= v.multiply_pipeline(PIPELINE_DEPTH-1).xerc.so or ov;
end if;
end if;

rin <= v;

@ -40,10 +40,8 @@ begin

m1.valid <= '1';
m1.insn_type <= OP_MUL_L64;
m1.write_reg <= "10001";
m1.data1 <= '0' & x"0000000000001000";
m1.data2 <= '0' & x"0000000000001111";
m1.rc <= '0';

wait for clk_period;
assert m2.valid = '0';
@ -58,15 +56,12 @@ begin

wait for clk_period;
assert m2.valid = '1';
assert m2.write_reg_nr = "10001";
assert m2.write_reg_data = x"0000000001111000";
assert m2.rc = '0';

wait for clk_period;
assert m2.valid = '0';

m1.valid <= '1';
m1.rc <= '1';

wait for clk_period;
assert m2.valid = '0';
@ -75,9 +70,7 @@ begin

wait for clk_period * (pipeline_depth-1);
assert m2.valid = '1';
assert m2.write_reg_nr = "10001";
assert m2.write_reg_data = x"0000000001111000";
assert m2.rc = '1';

-- test mulld
mulld_loop : for i in 0 to 1000 loop

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