xics: Add simple ICS

Move the external interrupt generation to a separate module
"ICS" (source controller) which a register per source containing
currently only the priority control.

Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
pull/210/head
Benjamin Herrenschmidt 5 years ago
parent 8080168327
commit 5c2fc47e2c

@ -78,6 +78,16 @@ package common is


type irq_state_t is (WRITE_SRR0, WRITE_SRR1); type irq_state_t is (WRITE_SRR0, WRITE_SRR1);


-- For now, fixed 16 sources, make this either a parametric
-- package of some sort or an unconstrainted array.
type ics_to_icp_t is record
-- Level interrupts only, ICS just keeps prsenting the
-- highest priority interrupt. Once handling edge, something
-- smarter involving handshake & reject support will be needed
src : std_ulogic_vector(3 downto 0);
pri : std_ulogic_vector(7 downto 0);
end record;

-- This needs to die... -- This needs to die...
type ctrl_t is record type ctrl_t is record
tb: std_ulogic_vector(63 downto 0); tb: std_ulogic_vector(63 downto 0);

@ -11,7 +11,8 @@


#define SYSCON_BASE 0xc0000000 /* System control regs */ #define SYSCON_BASE 0xc0000000 /* System control regs */
#define UART_BASE 0xc0002000 /* UART */ #define UART_BASE 0xc0002000 /* UART */
#define XICS_BASE 0xc0004000 /* Interrupt controller */ #define XICS_ICP_BASE 0xc0004000 /* Interrupt controller */
#define XICS_ICS_BASE 0xc0005000 /* Interrupt controller */
#define SPI_FCTRL_BASE 0xc0006000 /* SPI flash controller registers */ #define SPI_FCTRL_BASE 0xc0006000 /* SPI flash controller registers */
#define DRAM_CTRL_BASE 0xc8000000 /* LiteDRAM control registers */ #define DRAM_CTRL_BASE 0xc8000000 /* LiteDRAM control registers */
#define SPI_FLASH_BASE 0xf0000000 /* SPI Flash memory map */ #define SPI_FLASH_BASE 0xf0000000 /* SPI Flash memory map */

@ -21,6 +21,7 @@ use work.wishbone_types.all;
-- 0xc0000000: SYSCON -- 0xc0000000: SYSCON
-- 0xc0002000: UART0 -- 0xc0002000: UART0
-- 0xc0004000: XICS ICP -- 0xc0004000: XICS ICP
-- 0xc0005000: XICS ICS
-- 0xc0006000: SPI Flash controller -- 0xc0006000: SPI Flash controller
-- 0xc8nnnnnn: External IO bus -- 0xc8nnnnnn: External IO bus
-- 0xf0000000: Flash "ROM" mapping -- 0xf0000000: Flash "ROM" mapping
@ -130,12 +131,14 @@ architecture behaviour of soc is
signal wb_spiflash_is_reg : std_ulogic; signal wb_spiflash_is_reg : std_ulogic;
signal wb_spiflash_is_map : std_ulogic; signal wb_spiflash_is_map : std_ulogic;


-- XICS0 signals: -- XICS signals:
signal wb_xics0_in : wb_io_master_out; signal wb_xics_icp_in : wb_io_master_out;
signal wb_xics0_out : wb_io_slave_out; signal wb_xics_icp_out : wb_io_slave_out;
signal int_level_in : std_ulogic_vector(15 downto 0); signal wb_xics_ics_in : wb_io_master_out;

signal wb_xics_ics_out : wb_io_slave_out;
signal core_ext_irq : std_ulogic; signal int_level_in : std_ulogic_vector(15 downto 0);
signal ics_to_icp : ics_to_icp_t;
signal core_ext_irq : std_ulogic;


-- Main memory signals: -- Main memory signals:
signal wb_bram_in : wishbone_master_out; signal wb_bram_in : wishbone_master_out;
@ -171,7 +174,8 @@ architecture behaviour of soc is
-- IO branch split: -- IO branch split:
type slave_io_type is (SLAVE_IO_SYSCON, type slave_io_type is (SLAVE_IO_SYSCON,
SLAVE_IO_UART, SLAVE_IO_UART,
SLAVE_IO_ICP_0, SLAVE_IO_ICP,
SLAVE_IO_ICS,
SLAVE_IO_SPI_FLASH_REG, SLAVE_IO_SPI_FLASH_REG,
SLAVE_IO_SPI_FLASH_MAP, SLAVE_IO_SPI_FLASH_MAP,
SLAVE_IO_EXTERNAL, SLAVE_IO_EXTERNAL,
@ -441,7 +445,8 @@ begin
-- IO wishbone slave intercon. -- IO wishbone slave intercon.
-- --
slave_io_intercon: process(wb_sio_out, wb_syscon_out, wb_uart0_out, slave_io_intercon: process(wb_sio_out, wb_syscon_out, wb_uart0_out,
wb_ext_io_out, wb_xics0_out, wb_spiflash_out) wb_ext_io_out, wb_xics_icp_out, wb_xics_ics_out,
wb_spiflash_out)
variable slave_io : slave_io_type; variable slave_io : slave_io_type;


variable match : std_ulogic_vector(31 downto 12); variable match : std_ulogic_vector(31 downto 12);
@ -462,7 +467,9 @@ begin
elsif std_match(match, x"C8---") then elsif std_match(match, x"C8---") then
slave_io := SLAVE_IO_EXTERNAL; slave_io := SLAVE_IO_EXTERNAL;
elsif std_match(match, x"C0004") then elsif std_match(match, x"C0004") then
slave_io := SLAVE_IO_ICP_0; slave_io := SLAVE_IO_ICP;
elsif std_match(match, x"C0005") then
slave_io := SLAVE_IO_ICS;
elsif std_match(match, x"C0006") then elsif std_match(match, x"C0006") then
slave_io := SLAVE_IO_SPI_FLASH_REG; slave_io := SLAVE_IO_SPI_FLASH_REG;
end if; end if;
@ -474,11 +481,15 @@ begin
wb_spiflash_is_reg <= '0'; wb_spiflash_is_reg <= '0';
wb_spiflash_is_map <= '0'; wb_spiflash_is_map <= '0';


-- Only give xics 8 bits of wb addr -- Only give xics 8 bits of wb addr (for now...)
wb_xics0_in <= wb_sio_out; wb_xics_icp_in <= wb_sio_out;
wb_xics0_in.adr <= (others => '0'); wb_xics_icp_in.adr <= (others => '0');
wb_xics0_in.adr(7 downto 0) <= wb_sio_out.adr(7 downto 0); wb_xics_icp_in.adr(7 downto 0) <= wb_sio_out.adr(7 downto 0);
wb_xics0_in.cyc <= '0'; wb_xics_icp_in.cyc <= '0';
wb_xics_ics_in <= wb_sio_out;
wb_xics_ics_in.adr <= (others => '0');
wb_xics_ics_in.adr(11 downto 0) <= wb_sio_out.adr(11 downto 0);
wb_xics_ics_in.cyc <= '0';


wb_ext_io_in <= wb_sio_out; wb_ext_io_in <= wb_sio_out;
wb_ext_io_in.cyc <= '0'; wb_ext_io_in.cyc <= '0';
@ -521,9 +532,12 @@ begin
when SLAVE_IO_UART => when SLAVE_IO_UART =>
wb_uart0_in.cyc <= wb_sio_out.cyc; wb_uart0_in.cyc <= wb_sio_out.cyc;
wb_sio_in <= wb_uart0_out; wb_sio_in <= wb_uart0_out;
when SLAVE_IO_ICP_0 => when SLAVE_IO_ICP =>
wb_xics0_in.cyc <= wb_sio_out.cyc; wb_xics_icp_in.cyc <= wb_sio_out.cyc;
wb_sio_in <= wb_xics0_out; wb_sio_in <= wb_xics_icp_out;
when SLAVE_IO_ICS =>
wb_xics_ics_in.cyc <= wb_sio_out.cyc;
wb_sio_in <= wb_xics_ics_out;
when SLAVE_IO_SPI_FLASH_MAP => when SLAVE_IO_SPI_FLASH_MAP =>
-- Clear top bits so they don't make their way to the -- Clear top bits so they don't make their way to the
-- fash chip. -- fash chip.
@ -614,17 +628,27 @@ begin
wb_spiflash_out.stall <= wb_spiflash_in.cyc and not wb_spiflash_out.ack; wb_spiflash_out.stall <= wb_spiflash_in.cyc and not wb_spiflash_out.ack;
end generate; end generate;


xics0: entity work.xics xics_icp: entity work.xics_icp
port map(
clk => system_clk,
rst => rst_xics,
wb_in => wb_xics_icp_in,
wb_out => wb_xics_icp_out,
ics_in => ics_to_icp,
core_irq_out => core_ext_irq
);

xics_ics: entity work.xics_ics
generic map( generic map(
LEVEL_NUM => 16 SRC_NUM => 16
) )
port map( port map(
clk => system_clk, clk => system_clk,
rst => rst_xics, rst => rst_xics,
wb_in => wb_xics0_in, wb_in => wb_xics_ics_in,
wb_out => wb_xics0_out, wb_out => wb_xics_ics_out,
int_level_in => int_level_in, int_level_in => int_level_in,
core_irq_out => core_ext_irq icp_out => ics_to_icp
); );


-- Assign external interrupts -- Assign external interrupts

Binary file not shown.

@ -1,3 +1,4 @@
Test 0:PASS Test 0:PASS
Test 1:PASS Test 1:PASS
Test 2:PASS Test 2:PASS
Test 3:PASS

@ -74,6 +74,8 @@ void ipi_isr(void) {
debug_puts(IPI); debug_puts(IPI);


isrs_run |= ISR_IPI; isrs_run |= ISR_IPI;

icp_write8(XICS_MFRR, 0xff);
} }




@ -109,6 +111,8 @@ struct isr_op isr_table[] = {
bool ipi_running; bool ipi_running;


#define ISR "ISR XISR=" #define ISR "ISR XISR="
#define PRIO " PRIO="
#define CPPR " CPPR="
void isr(void) void isr(void)
{ {
struct isr_op *op; struct isr_op *op;
@ -117,11 +121,15 @@ void isr(void)
assert(!ipi_running); // check we aren't reentrant assert(!ipi_running); // check we aren't reentrant
ipi_running = true; ipi_running = true;


xirr = xics_read32(XICS_XIRR); // read hardware irq source xirr = icp_read32(XICS_XIRR); // read hardware irq source


#ifdef DEBUG #ifdef DEBUG
puts(ISR); puts(ISR);
print_number(xirr & 0xff); print_number(xirr & 0xff);
puts(PRIO);
print_number(xirr >> 24);
puts(CPPR);
print_number(icp_read8(XICS_XIRR_POLL));
puts("\n"); puts("\n");
#endif #endif


@ -135,7 +143,7 @@ void isr(void)
op++; op++;
} }


xics_write32(XICS_XIRR, xirr); // EOI icp_write32(XICS_XIRR, xirr); // EOI


ipi_running = false; ipi_running = false;
} }
@ -143,45 +151,87 @@ void isr(void)
/*****************************************/ /*****************************************/


int xics_test_0(void) int xics_test_0(void)
{
uint32_t v0, v1;

v0 = ics_read_xive(0);
v1 = ics_read_xive(1);
#ifdef DEBUG
puts("\n");
puts("xive(0) bfr: ");
print_number(v0);
puts("\n");
puts("xive(1) bfr: ");
print_number(v1);
puts("\n");
#endif
assert(v0 = 0xff);
assert(v1 = 0xff);

ics_write_xive(0xaa, 0);
ics_write_xive(0x55, 1);
v0 = ics_read_xive(0);
v1 = ics_read_xive(1);
#ifdef DEBUG
puts("\n");
puts("xive(0) aft: ");
print_number(v0);
puts("\n");
puts("xive(1) aft: ");
print_number(v1);
puts("\n");
#endif
assert(v0 = 0xaa);
assert(v1 = 0x55);

ics_write_xive(0xff, 0);
ics_write_xive(0xff, 1);
return 0;
}

int xics_test_1(void)
{ {
// setup // setup
xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts
isrs_run = 0; isrs_run = 0;


xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts


// trigger two interrupts // trigger two interrupts
potato_uart_irq_en(); // cause 0x500 interrupt potato_uart_irq_en(); // cause 0x500 interrupt
xics_write8(XICS_MFRR, 0x05); // cause 0x500 interrupt ics_write_xive(0x80, 0);
icp_write8(XICS_MFRR, 0x05); // cause 0x500 interrupt


// still masked, so shouldn't happen yet // still masked, so shouldn't happen yet
delay(); delay();
assert(isrs_run == 0); assert(isrs_run == 0);


// unmask IPI only // unmask IPI only
xics_write8(XICS_XIRR, 0x40); icp_write8(XICS_XIRR, 0x40);
delay(); delay();
assert(isrs_run == ISR_IPI); assert(isrs_run == ISR_IPI);


// unmask UART // unmask UART
xics_write8(XICS_XIRR, 0xc0); icp_write8(XICS_XIRR, 0xc0);
delay(); delay();
assert(isrs_run == (ISR_IPI | ISR_UART)); assert(isrs_run == (ISR_IPI | ISR_UART));


// cleanup // cleanup
xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts
potato_uart_irq_dis();
ics_write_xive(0, 0);
isrs_run = 0; isrs_run = 0;


return 0; return 0;
} }


int xics_test_1(void) int xics_test_2(void)
{ {
// setup // setup
xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts
isrs_run = 0; isrs_run = 0;


xics_write8(XICS_XIRR, 0xff); // allow all interrupts icp_write8(XICS_XIRR, 0xff); // allow all interrupts


// should be none pending // should be none pending
delay(); delay();
@ -189,13 +239,14 @@ int xics_test_1(void)


// trigger both // trigger both
potato_uart_irq_en(); // cause 0x500 interrupt potato_uart_irq_en(); // cause 0x500 interrupt
xics_write8(XICS_MFRR, 0x05); // cause 0x500 interrupt icp_write8(XICS_MFRR, 0x05); // cause 0x500 interrupt


delay(); delay();
assert(isrs_run == (ISR_IPI | ISR_UART)); assert(isrs_run == (ISR_IPI | ISR_UART));


// cleanup // cleanup
xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts
potato_uart_irq_dis();
isrs_run = 0; isrs_run = 0;


return 0; return 0;
@ -206,19 +257,19 @@ void mtmsrd(uint64_t val)
__asm__ volatile("mtmsrd %0" : : "r" (val)); __asm__ volatile("mtmsrd %0" : : "r" (val));
} }


int xics_test_2(void) int xics_test_3(void)
{ {
// setup // setup
xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts
isrs_run = 0; isrs_run = 0;


// trigger interrupts with MSR[EE]=0 and show they are not run // trigger interrupts with MSR[EE]=0 and show they are not run
mtmsrd(0x9000000000000003); // EE off mtmsrd(0x9000000000000003); // EE off


xics_write8(XICS_XIRR, 0xff); // allow all interrupts icp_write8(XICS_XIRR, 0xff); // allow all interrupts


// trigger an IPI // trigger an IPI
xics_write8(XICS_MFRR, 0x05); // cause 0x500 interrupt icp_write8(XICS_MFRR, 0x05); // cause 0x500 interrupt


delay(); delay();
assert(isrs_run == 0); assert(isrs_run == 0);
@ -228,7 +279,7 @@ int xics_test_2(void)
assert(isrs_run == ISR_IPI); assert(isrs_run == ISR_IPI);


// cleanup // cleanup
xics_write8(XICS_XIRR, 0x00); // mask all interrupts icp_write8(XICS_XIRR, 0x00); // mask all interrupts
isrs_run = 0; isrs_run = 0;


return 0; return 0;
@ -242,6 +293,7 @@ int (*tests[])(void) = {
xics_test_0, xics_test_0,
xics_test_1, xics_test_1,
xics_test_2, xics_test_2,
xics_test_3,
NULL NULL
}; };



@ -9,23 +9,33 @@


#define bswap32(x) (uint32_t)__builtin_bswap32((uint32_t)(x)) #define bswap32(x) (uint32_t)__builtin_bswap32((uint32_t)(x))


uint8_t xics_read8(int offset) uint8_t icp_read8(int offset)
{ {
return readb(XICS_BASE + offset); return readb(XICS_ICP_BASE + offset);
} }


void xics_write8(int offset, uint8_t val) void icp_write8(int offset, uint8_t val)
{ {
writeb(val, XICS_BASE + offset); writeb(val, XICS_ICP_BASE + offset);
} }


uint32_t xics_read32(int offset) uint32_t icp_read32(int offset)
{ {
return bswap32(readl(XICS_BASE + offset)); return bswap32(readl(XICS_ICP_BASE + offset));
} }


void xics_write32(int offset, uint32_t val) static inline void icp_write32(int offset, uint32_t val)
{ {
writel(bswap32(val), XICS_BASE + offset); writel(bswap32(val), XICS_ICP_BASE + offset);
}

uint32_t ics_read_xive(int irq)
{
return bswap32(readl(XICS_ICS_BASE + 0x800 + (irq << 2)));
}

void ics_write_xive(uint32_t val, int irq)
{
writel(bswap32(val), XICS_ICS_BASE + 0x800 + (irq << 2));
} }



@ -1,11 +1,13 @@
-- --
-- This is a simple XICS compliant interrupt controller. This is a -- This is a simple XICS compliant interrupt controller. This is a
-- Presenter (ICP) and Source (ICS) in a single unit with no routing -- Presenter (ICP) and Source (ICS) in two small units directly
-- layer. -- connected to each other with no routing layer.
-- --
-- The sources have a fixed IRQ priority set by HW_PRIORITY. The -- The sources have a configurable IRQ priority set a set of ICS
-- source id starts at 16 for int_level_in(0) and go up from -- registers in the source units.
-- there (ie int_level_in(1) is source id 17). --
-- The source ids start at 16 for int_level_in(0) and go up from
-- there (ie int_level_in(1) is source id 17). XXX Make a generic
-- --
-- The presentation layer will pick an interupt that is more -- The presentation layer will pick an interupt that is more
-- favourable than the current CPPR and present it via the XISR and -- favourable than the current CPPR and present it via the XISR and
@ -22,38 +24,31 @@ library work;
use work.common.all; use work.common.all;
use work.wishbone_types.all; use work.wishbone_types.all;


entity xics is entity xics_icp is
generic (
LEVEL_NUM : positive := 16
);
port ( port (
clk : in std_logic; clk : in std_logic;
rst : in std_logic; rst : in std_logic;


wb_in : in wb_io_master_out; wb_in : in wb_io_master_out;
wb_out : out wb_io_slave_out; wb_out : out wb_io_slave_out;

int_level_in : in std_ulogic_vector(LEVEL_NUM - 1 downto 0);


ics_in : in ics_to_icp_t;
core_irq_out : out std_ulogic core_irq_out : out std_ulogic
); );
end xics; end xics_icp;


architecture behaviour of xics is architecture behaviour of xics_icp is
type reg_internal_t is record type reg_internal_t is record
xisr : std_ulogic_vector(23 downto 0); xisr : std_ulogic_vector(23 downto 0);
cppr : std_ulogic_vector(7 downto 0); cppr : std_ulogic_vector(7 downto 0);
pending_priority : std_ulogic_vector(7 downto 0);
mfrr : std_ulogic_vector(7 downto 0); mfrr : std_ulogic_vector(7 downto 0);
mfrr_pending : std_ulogic;
irq : std_ulogic; irq : std_ulogic;
wb_rd_data : std_ulogic_vector(31 downto 0); wb_rd_data : std_ulogic_vector(31 downto 0);
wb_ack : std_ulogic; wb_ack : std_ulogic;
end record; end record;
constant reg_internal_init : reg_internal_t := constant reg_internal_init : reg_internal_t :=
(wb_ack => '0', (wb_ack => '0',
mfrr_pending => '0', mfrr => x"ff", -- mask everything on reset
mfrr => x"ff", -- no IPI on reset
irq => '0', irq => '0',
others => (others => '0')); others => (others => '0'));


@ -74,18 +69,19 @@ begin
begin begin
if rising_edge(clk) then if rising_edge(clk) then
r <= r_next; r <= r_next;

-- We delay core_irq_out by a cycle to help with timing
core_irq_out <= r.irq;
end if; end if;
end process; end process;


wb_out.dat <= r.wb_rd_data; wb_out.dat <= r.wb_rd_data;
wb_out.ack <= r.wb_ack; wb_out.ack <= r.wb_ack;
wb_out.stall <= '0'; -- never stall wishbone wb_out.stall <= '0'; -- never stall wishbone
core_irq_out <= r.irq;


comb : process(all) comb : process(all)
variable v : reg_internal_t; variable v : reg_internal_t;
variable xirr_accept_rd : std_ulogic; variable xirr_accept_rd : std_ulogic;
variable irq_eoi : std_ulogic;


function bswap(v : in std_ulogic_vector(31 downto 0)) return std_ulogic_vector is function bswap(v : in std_ulogic_vector(31 downto 0)) return std_ulogic_vector is
variable r : std_ulogic_vector(31 downto 0); variable r : std_ulogic_vector(31 downto 0);
@ -99,13 +95,14 @@ begin


variable be_in : std_ulogic_vector(31 downto 0); variable be_in : std_ulogic_vector(31 downto 0);
variable be_out : std_ulogic_vector(31 downto 0); variable be_out : std_ulogic_vector(31 downto 0);

variable pending_priority : std_ulogic_vector(7 downto 0);
begin begin
v := r; v := r;


v.wb_ack := '0'; v.wb_ack := '0';


xirr_accept_rd := '0'; xirr_accept_rd := '0';
irq_eoi := '0';


be_in := bswap(wb_in.dat); be_in := bswap(wb_in.dat);
be_out := (others => '0'); be_out := (others => '0');
@ -122,7 +119,6 @@ begin
v.cppr := be_in(31 downto 24); v.cppr := be_in(31 downto 24);
if wb_in.sel = x"f" then -- 4 byte if wb_in.sel = x"f" then -- 4 byte
report "ICP XIRR write word (EOI) :" & to_hstring(be_in); report "ICP XIRR write word (EOI) :" & to_hstring(be_in);
irq_eoi := '1';
elsif wb_in.sel = x"1" then -- 1 byte elsif wb_in.sel = x"1" then -- 1 byte
report "ICP XIRR write byte (CPPR):" & to_hstring(be_in(31 downto 24)); report "ICP XIRR write byte (CPPR):" & to_hstring(be_in(31 downto 24));
else else
@ -130,7 +126,6 @@ begin
end if; end if;
when MFRR => when MFRR =>
v.mfrr := be_in(31 downto 24); v.mfrr := be_in(31 downto 24);
v.mfrr_pending := '1';
if wb_in.sel = x"f" then -- 4 bytes if wb_in.sel = x"f" then -- 4 bytes
report "ICP MFRR write word:" & to_hstring(be_in); report "ICP MFRR write word:" & to_hstring(be_in);
elsif wb_in.sel = x"1" then -- 1 byte elsif wb_in.sel = x"1" then -- 1 byte
@ -161,49 +156,40 @@ begin
end if; end if;
end if; end if;


-- generate interrupt pending_priority := x"ff";
if r.irq = '0' then v.xisr := x"000000";
-- Here we just present any interrupt that's valid and v.irq := '0';
-- below cppr. For ordering, we ignore hardware
-- priorities.
if unsigned(HW_PRIORITY) < unsigned(r.cppr) then --
-- lower HW sources are higher priority
for i in LEVEL_NUM - 1 downto 0 loop
if int_level_in(i) = '1' then
v.irq := '1';
v.xisr := std_ulogic_vector(to_unsigned(16 + i, 24));
v.pending_priority := HW_PRIORITY; -- hardware HW IRQs
end if;
end loop;
end if;


-- Do mfrr as a higher priority so mfrr_pending is cleared if ics_in.pri /= x"ff" then
if unsigned(r.mfrr) < unsigned(r.cppr) then -- v.xisr := x"00001" & ics_in.src;
report "XICS: MFRR INTERRUPT"; pending_priority := ics_in.pri;
-- IPI end if;
if r.mfrr_pending = '1' then
v.irq := '1'; -- Check MFRR
v.xisr := x"000002"; -- special XICS MFRR IRQ source number if unsigned(r.mfrr) < unsigned(pending_priority) then --
v.pending_priority := r.mfrr; v.xisr := x"000002"; -- special XICS MFRR IRQ source number
v.mfrr_pending := '0'; pending_priority := r.mfrr;
end if; end if;
end if;
end if;


-- Accept the interrupt -- Accept the interrupt
if xirr_accept_rd = '1' then if xirr_accept_rd = '1' then
report "XICS: ACCEPT" & report "XICS: ICP ACCEPT" &
" cppr:" & to_hstring(r.cppr) & " cppr:" & to_hstring(r.cppr) &
" xisr:" & to_hstring(r.xisr) & " xisr:" & to_hstring(r.xisr) &
" mfrr:" & to_hstring(r.mfrr); " mfrr:" & to_hstring(r.mfrr);
v.cppr := r.pending_priority; v.cppr := pending_priority;
end if; end if;


v.wb_rd_data := bswap(be_out); v.wb_rd_data := bswap(be_out);


if irq_eoi = '1' then if unsigned(pending_priority) < unsigned(v.cppr) then
v.irq := '0'; if r.irq = '0' then
end if; report "IRQ set";
end if;
v.irq := '1';
elsif r.irq = '1' then
report "IRQ clr";
end if;


if rst = '1' then if rst = '1' then
v := reg_internal_init; v := reg_internal_init;
@ -214,3 +200,192 @@ begin
end process; end process;


end architecture behaviour; end architecture behaviour;

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

library work;
use work.common.all;
use work.wishbone_types.all;

entity xics_ics is
generic (
SRC_NUM : positive := 16
);
port (
clk : in std_logic;
rst : in std_logic;

wb_in : in wb_io_master_out;
wb_out : out wb_io_slave_out;

int_level_in : in std_ulogic_vector(SRC_NUM - 1 downto 0);
icp_out : out ics_to_icp_t
);
end xics_ics;

architecture rtl of xics_ics is

subtype pri_t is std_ulogic_vector(7 downto 0);
type xive_t is record
pri : pri_t;
end record;
type xive_array_t is array(0 to SRC_NUM-1) of xive_t;
signal xives : xive_array_t;

signal wb_valid : std_ulogic;
signal reg_idx : integer range 0 to SRC_NUM - 1;
signal icp_out_next : ics_to_icp_t;
signal int_level_l : std_ulogic_vector(SRC_NUM - 1 downto 0);

function bswap(v : in std_ulogic_vector(31 downto 0)) return std_ulogic_vector is
variable r : std_ulogic_vector(31 downto 0);
begin
r( 7 downto 0) := v(31 downto 24);
r(15 downto 8) := v(23 downto 16);
r(23 downto 16) := v(15 downto 8);
r(31 downto 24) := v( 7 downto 0);
return r;
end function;

-- Register map
-- 0 : Config (currently hard wired base irq#)
-- 4 : Debug/diagnostics
-- 800 : XIVE0
-- 804 : XIVE1 ...
--
-- Config register format:
--
-- 23.. 0 : Interrupt base (hard wired to 16)
--
-- XIVE register format:
--
-- 31 : input bit (reflects interrupt input)
-- 30 : reserved
-- 29 : P (mirrors input for now)
-- 28 : Q (not implemented in this version)
-- 30 .. : reserved
-- 19 .. 8 : target (not implemented in this version)
-- 7 .. 0 : prio/mask

signal reg_is_xive : std_ulogic;
signal reg_is_config : std_ulogic;
signal reg_is_debug : std_ulogic;

begin

assert SRC_NUM = 16 report "Fixup address decode with log2";

reg_is_xive <= wb_in.adr(11);
reg_is_config <= '1' when wb_in.adr(11 downto 0) = x"000" else '0';
reg_is_debug <= '1' when wb_in.adr(11 downto 0) = x"004" else '0';

-- Register index XX FIXME: figure out bits from SRC_NUM
reg_idx <= to_integer(unsigned(wb_in.adr(5 downto 2)));

-- Latch interrupt inputs for timing
int_latch: process(clk)
begin
if rising_edge(clk) then
int_level_l <= int_level_in;
end if;
end process;

-- We don't stall. Acks are sent by the read machine one cycle
-- after a request, but we can handle one access per cycle.
wb_out.stall <= '0';
wb_valid <= wb_in.cyc and wb_in.stb;

-- Big read mux. This could be replaced by a slower state
-- machine iterating registers instead if timing gets tight.
reg_read: process(clk)
variable be_out : std_ulogic_vector(31 downto 0);
begin
if rising_edge(clk) then
be_out := (others => '0');

if reg_is_xive = '1' then
be_out := int_level_l(reg_idx) &
'0' &
int_level_l(reg_idx) &
'0' &
x"00000" &
xives(reg_idx).pri;
elsif reg_is_config = '1' then
be_out := std_ulogic_vector(to_unsigned(SRC_NUM, 32));
elsif reg_is_debug = '1' then
be_out := x"00000" & icp_out_next.src & icp_out_next.pri;
end if;
wb_out.dat <= bswap(be_out);
wb_out.ack <= wb_valid;
end if;
end process;

-- Register write machine
reg_write: process(clk)
variable be_in : std_ulogic_vector(31 downto 0);
begin
-- Byteswapped input
be_in := bswap(wb_in.dat);

if rising_edge(clk) then
if rst = '1' then
for i in 0 to SRC_NUM - 1 loop
xives(i) <= (pri => x"ff");
end loop;
elsif wb_valid = '1' and wb_in.we = '1' then
if reg_is_xive then
-- TODO: When adding support for other bits, make sure to
-- properly implement wb_in.sel to allow partial writes.
xives(reg_idx).pri <= be_in(7 downto 0);
report "ICS irq " & integer'image(reg_idx) & " set to:" & to_hstring(be_in(7 downto 0));
end if;
end if;
end if;
end process;

-- generate interrupt. This is a simple combinational process,
-- potentially wasteul in HW for large number of interrupts.
--
-- could be replaced with iterative state machines and a message
-- system between ICSs' (plural) and ICP incl. reject etc...
--
irq_gen_sync: process(clk)
begin
if rising_edge(clk) then
icp_out <= icp_out_next;
end if;
end process;

irq_gen: process(all)
variable max_idx : integer range 0 to SRC_NUM-1;
variable max_pri : pri_t;

-- A more favored than b ?
function a_mf_b(a: pri_t; b: pri_t) return boolean is
variable a_i : integer range 0 to 255;
variable b_i : integer range 0 to 255;
begin
a_i := to_integer(unsigned(a));
b_i := to_integer(unsigned(b));
return a < b;
end function;
begin
-- XXX FIXME: Use a tree
max_pri := x"ff";
max_idx := 0;
for i in 0 to SRC_NUM - 1 loop
if int_level_l(i) = '1' and a_mf_b(xives(i).pri, max_pri) then
max_pri := xives(i).pri;
max_idx := i;
end if;
end loop;
if max_pri /= x"ff" then
report "MFI: " & integer'image(max_idx) & " pri=" & to_hstring(max_pri);
end if;
icp_out_next.src <= std_ulogic_vector(to_unsigned(max_idx, 4));
icp_out_next.pri <= max_pri;
end process;

end architecture rtl;

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