microwatt/gpr_hazard.vhdl

library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;

entity gpr_hazard is
    generic (
        PIPELINE_DEPTH : natural := 2
        );
    port(
        clk                : in std_ulogic;
	stall_in           : in std_ulogic;

        gpr_write_valid_in : in std_ulogic;
        gpr_write_in       : in std_ulogic_vector(5 downto 0);
        bypass_avail       : in std_ulogic;
        gpr_read_valid_in  : in std_ulogic;
        gpr_read_in        : in std_ulogic_vector(5 downto 0);

        stall_out          : out std_ulogic;
        use_bypass         : out std_ulogic
        );
end entity gpr_hazard;
architecture behaviour of gpr_hazard is
    type pipeline_entry_type is record
        valid  : std_ulogic;
        bypass : std_ulogic;
        gpr    : std_ulogic_vector(5 downto 0);
    end record;
    constant pipeline_entry_init : pipeline_entry_type := (valid => '0', bypass => '0', gpr => (others => '0'));

    type pipeline_t is array(0 to PIPELINE_DEPTH-1) of pipeline_entry_type;
    constant pipeline_t_init : pipeline_t := (others => pipeline_entry_init);

    signal r, rin : pipeline_t := pipeline_t_init;
begin
    gpr_hazard0: process(clk)
    begin
        if rising_edge(clk) then
            r <= rin;
        end if;
    end process;

    gpr_hazard1: process(all)
        variable v     : pipeline_t;
    begin
        v := r;

        stall_out <= '0';
        use_bypass <= '0';
        if gpr_read_valid_in = '1' then
            if r(0).valid = '1' and r(0).gpr = gpr_read_in then
                if r(0).bypass = '1' and stall_in = '0' then
                    use_bypass <= '1';
                else
                    stall_out <= '1';
                end if;
            end if;
            loop_0: for i in 1 to PIPELINE_DEPTH-1 loop
                if r(i).valid = '1' and r(i).gpr = gpr_read_in then
                    if r(i).bypass = '1' then
                        use_bypass <= '1';
                    else
                        stall_out <= '1';
                    end if;
                end if;
            end loop;
        end if;

        if stall_in = '0' then
            v(0).valid  := gpr_write_valid_in;
            v(0).bypass := bypass_avail;
            v(0).gpr    := gpr_write_in;
            loop_1: for i in 1 to PIPELINE_DEPTH-1 loop
                -- propagate to next slot
                v(i).valid  := r(i-1).valid;
                v(i).bypass := r(i-1).bypass;
                v(i).gpr    := r(i-1).gpr;
            end loop;

        else
            -- stage 0 stalled, so stage 1 becomes empty
            loop_1b: for i in 1 to PIPELINE_DEPTH-1 loop
                -- propagate to next slot
                if i = 1 then
                    v(i).valid := '0';
                else
                    v(i).valid  := r(i-1).valid;
                    v(i).bypass := r(i-1).bypass;
                    v(i).gpr    := r(i-1).gpr;
                end if;
            end loop;
        end if;

        -- update registers
        rin <= v;

    end process;
end;
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`library ieee;`
			`use ieee.std_logic_1164.all;`
			`use ieee.numeric_std.all;`

			`entity gpr_hazard is`
			`generic (`
			`PIPELINE_DEPTH : natural := 2`
			`);`
			`port(`
sprs: Store common SPRs in register file This stores the most common SPRs in the register file. This includes CTR and LR and a not yet final list of others. The register file is set to 64 entries for now. Specific types are defined that can represent a GPR index (gpr_index_t) or a GPR/SPR index (gspr_index_t) along with conversion functions between the two. On order to deal with some forms of branch updating both LR and CTR, we introduced a delayed update of LR after a branch link. Note: We currently stall the pipeline on such a delayed branch, but we could avoid stalling fetch in that specific case as we know we have a branch delay. We could also limit that to the specific case where we need to update both CTR and LR. This allows us to make bcreg, mtspr and mfspr pipelined. decode1 will automatically force the single issue flag on mfspr/mtspr to a "slow" SPR. [paulus@ozlabs.org - fix direction of decode2.stall_in] Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org> Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`clk : in std_ulogic;`
			`stall_in : in std_ulogic;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago
			`gpr_write_valid_in : in std_ulogic;`
sprs: Store common SPRs in register file This stores the most common SPRs in the register file. This includes CTR and LR and a not yet final list of others. The register file is set to 64 entries for now. Specific types are defined that can represent a GPR index (gpr_index_t) or a GPR/SPR index (gspr_index_t) along with conversion functions between the two. On order to deal with some forms of branch updating both LR and CTR, we introduced a delayed update of LR after a branch link. Note: We currently stall the pipeline on such a delayed branch, but we could avoid stalling fetch in that specific case as we know we have a branch delay. We could also limit that to the specific case where we need to update both CTR and LR. This allows us to make bcreg, mtspr and mfspr pipelined. decode1 will automatically force the single issue flag on mfspr/mtspr to a "slow" SPR. [paulus@ozlabs.org - fix direction of decode2.stall_in] Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org> Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`gpr_write_in : in std_ulogic_vector(5 downto 0);`
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`bypass_avail : in std_ulogic;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`gpr_read_valid_in : in std_ulogic;`
sprs: Store common SPRs in register file This stores the most common SPRs in the register file. This includes CTR and LR and a not yet final list of others. The register file is set to 64 entries for now. Specific types are defined that can represent a GPR index (gpr_index_t) or a GPR/SPR index (gspr_index_t) along with conversion functions between the two. On order to deal with some forms of branch updating both LR and CTR, we introduced a delayed update of LR after a branch link. Note: We currently stall the pipeline on such a delayed branch, but we could avoid stalling fetch in that specific case as we know we have a branch delay. We could also limit that to the specific case where we need to update both CTR and LR. This allows us to make bcreg, mtspr and mfspr pipelined. decode1 will automatically force the single issue flag on mfspr/mtspr to a "slow" SPR. [paulus@ozlabs.org - fix direction of decode2.stall_in] Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org> Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`gpr_read_in : in std_ulogic_vector(5 downto 0);`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`stall_out : out std_ulogic;`
			`use_bypass : out std_ulogic`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`);`
			`end entity gpr_hazard;`
			`architecture behaviour of gpr_hazard is`
			`type pipeline_entry_type is record`
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`valid : std_ulogic;`
			`bypass : std_ulogic;`
			`gpr : std_ulogic_vector(5 downto 0);`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`end record;`
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`constant pipeline_entry_init : pipeline_entry_type := (valid => '0', bypass => '0', gpr => (others => '0'));`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago
			`type pipeline_t is array(0 to PIPELINE_DEPTH-1) of pipeline_entry_type;`
			`constant pipeline_t_init : pipeline_t := (others => pipeline_entry_init);`

			`signal r, rin : pipeline_t := pipeline_t_init;`
			`begin`
			`gpr_hazard0: process(clk)`
			`begin`
			`if rising_edge(clk) then`
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`r <= rin;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`end if;`
			`end process;`

			`gpr_hazard1: process(all)`
			`variable v : pipeline_t;`
			`begin`
			`v := r;`

			`stall_out <= '0';`
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`use_bypass <= '0';`
			`if gpr_read_valid_in = '1' then`
			`if r(0).valid = '1' and r(0).gpr = gpr_read_in then`
			`if r(0).bypass = '1' and stall_in = '0' then`
			`use_bypass <= '1';`
			`else`
			`stall_out <= '1';`
			`end if;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`end if;`
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`loop_0: for i in 1 to PIPELINE_DEPTH-1 loop`
			`if r(i).valid = '1' and r(i).gpr = gpr_read_in then`
			`if r(i).bypass = '1' then`
			`use_bypass <= '1';`
			`else`
			`stall_out <= '1';`
			`end if;`
			`end if;`
			`end loop;`
			`end if;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`if stall_in = '0' then`
			`v(0).valid := gpr_write_valid_in;`
			`v(0).bypass := bypass_avail;`
			`v(0).gpr := gpr_write_in;`
			`loop_1: for i in 1 to PIPELINE_DEPTH-1 loop`
			`-- propagate to next slot`
			`v(i).valid := r(i-1).valid;`
			`v(i).bypass := r(i-1).bypass;`
			`v(i).gpr := r(i-1).gpr;`
			`end loop;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago
execute: Implement bypass from output of execute1 to input This enables back-to-back execution of integer instructions where the first instruction writes a GPR and the second reads the same GPR. This is done with a set of multiplexers at the start of execute1 which enable any of the three input operands to be taken from the output of execute1 (i.e. r.e.write_data) rather than the input from decode2 (i.e. e_in.read_data[123]). This also requires changes to the hazard detection and handling. Decode2 generates a signal indicating that the GPR being written is available for bypass, which is true for instructions that are executed in execute1 (rather than loadstore1/dcache). The gpr_hazard module stores this "bypassable" bit, and if the same GPR needs to be read by a subsequent instruction, it outputs a "use_bypass" signal rather than generating a stall. The use_bypass signal is then latched at the output of decode2 and passed down to execute1 to control the input multiplexer. At the moment there is no bypass on the inputs to loadstore1, but that is OK because all load and store instructions are marked as single-issue. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 5 years ago			`else`
			`-- stage 0 stalled, so stage 1 becomes empty`
			`loop_1b: for i in 1 to PIPELINE_DEPTH-1 loop`
			`-- propagate to next slot`
			`if i = 1 then`
			`v(i).valid := '0';`
			`else`
			`v(i).valid := r(i-1).valid;`
			`v(i).bypass := r(i-1).bypass;`
			`v(i).gpr := r(i-1).gpr;`
			`end if;`
			`end loop;`
Add GPR hazard detection Check GPRs against any writers in the pipeline. All instructions are still marked single in pipeline at this stage. Signed-off-by: Anton Blanchard <anton@linux.ibm.com> 5 years ago			`end if;`

			`-- update registers`
			`rin <= v;`

			`end process;`
			`end;`