qemu/include/hw/ppc/xive_regs.h

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/*
* QEMU PowerPC XIVE internal structure definitions
*
*
* The XIVE structures are accessed by the HW and their format is
* architected to be big-endian. Some macros are provided to ease
* access to the different fields.
*
*
* Copyright (c) 2016-2018, IBM Corporation.
*
* This code is licensed under the GPL version 2 or later. See the
* COPYING file in the top-level directory.
*/
#ifndef PPC_XIVE_REGS_H
#define PPC_XIVE_REGS_H
#include "qemu/bswap.h"
#include "qemu/host-utils.h"
/*
* Interrupt source number encoding on PowerBUS
*/
ppc/pnv: Improve trigger data definition The trigger data is used for both triggers of a HW source interrupts, PHB, PSI, and triggers for rerouting interrupts between interrupt controllers. When an interrupt is rerouted, the trigger data follows an "END trigger" format. In that case, the remote IC needs EAS containing an END index to perform a lookup of an END. An END trigger, bit0 of word0 set to '1', is defined as : |0123|4567|0123|4567|0123|4567|0123|4567| W0 E=1 |1P--|BLOC| END IDX | W1 E=1 |M | END DATA | An EAS is defined as : |0123|4567|0123|4567|0123|4567|0123|4567| W0 |V---|BLOC| END IDX | W1 |M | END DATA | The END trigger adds an extra 'PQ' bit, bit1 of word0 set to '1', signaling that the PQ bits have been checked. That bit is unused in the initial EAS definition. When a HW device performs the trigger, the trigger data follows an "EAS trigger" format because the trigger data in that case contains an EAS index which the IC needs to look for. An EAS trigger, bit0 of word0 set to '0', is defined as : |0123|4567|0123|4567|0123|4567|0123|4567| W0 E=0 |0P--|---- ---- ---- ---- ---- ---- ----| W1 E=0 |BLOC| EAS INDEX | There is also a 'PQ' bit, bit1 of word0 to '1', signaling that the PQ bits have been checked. Introduce these new trigger bits and rename the XIVE_SRCNO macros in XIVE_EAS to reflect better the nature of the data. Signed-off-by: Cédric Le Goater <clg@kaod.org> Message-Id: <20191007084102.29776-2-clg@kaod.org> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-10-07 11:40:54 +03:00
/*
* Trigger data definition
*
* The trigger definition is used for triggers both for HW source
* interrupts (PHB, PSI), as well as for rerouting interrupts between
* Interrupt Controller.
*
* HW source controllers set bit0 of word0 to 0 as they provide EAS
* information (EAS block + EAS index) in the 8 byte data and not END
* information, which is use for rerouting interrupts.
*
* bit1 of word0 to 1 signals that the state bit check has been
* performed.
*/
#define XIVE_TRIGGER_END PPC_BIT(0)
#define XIVE_TRIGGER_PQ PPC_BIT(1)
/*
* QEMU macros to manipulate the trigger payload in native endian
*/
#define XIVE_EAS_BLOCK(n) (((n) >> 28) & 0xf)
#define XIVE_EAS_INDEX(n) ((n) & 0x0fffffff)
#define XIVE_EAS(blk, idx) ((uint32_t)(blk) << 28 | (idx))
ppc/xive: introduce the XIVE interrupt thread context Each POWER9 processor chip has a XIVE presenter that can generate four different exceptions to its threads: - hypervisor exception, - O/S exception - Event-Based Branch (EBB) - msgsnd (doorbell). Each exception has a state independent from the others called a Thread Interrupt Management context. This context is a set of registers which lets the thread handle priority management and interrupt acknowledgment among other things. The most important ones being : - Interrupt Priority Register (PIPR) - Interrupt Pending Buffer (IPB) - Current Processor Priority (CPPR) - Notification Source Register (NSR) These registers are accessible through a specific MMIO region, called the Thread Interrupt Management Area (TIMA), four aligned pages, each exposing a different view of the registers. First page (page address ending in 0b00) gives access to the entire context and is reserved for the ring 0 view for the physical thread context. The second (page address ending in 0b01) is for the hypervisor, ring 1 view. The third (page address ending in 0b10) is for the operating system, ring 2 view. The fourth (page address ending in 0b11) is for user level, ring 3 view. The thread interrupt context is modeled with a XiveTCTX object containing the values of the different exception registers. The TIMA region is mapped at the same address for each CPU. Signed-off-by: Cédric Le Goater <clg@kaod.org> Reviewed-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2018-12-09 22:45:53 +03:00
#define TM_SHIFT 16
/* TM register offsets */
#define TM_QW0_USER 0x000 /* All rings */
#define TM_QW1_OS 0x010 /* Ring 0..2 */
#define TM_QW2_HV_POOL 0x020 /* Ring 0..1 */
#define TM_QW3_HV_PHYS 0x030 /* Ring 0..1 */
/* Byte offsets inside a QW QW0 QW1 QW2 QW3 */
#define TM_NSR 0x0 /* + + - + */
#define TM_CPPR 0x1 /* - + - + */
#define TM_IPB 0x2 /* - + + + */
#define TM_LSMFB 0x3 /* - + + + */
#define TM_ACK_CNT 0x4 /* - + - - */
#define TM_INC 0x5 /* - + - + */
#define TM_AGE 0x6 /* - + - + */
#define TM_PIPR 0x7 /* - + - + */
#define TM_WORD0 0x0
#define TM_WORD1 0x4
/*
* QW word 2 contains the valid bit at the top and other fields
* depending on the QW.
*/
#define TM_WORD2 0x8
ppc/xive: introduce the XIVE interrupt thread context Each POWER9 processor chip has a XIVE presenter that can generate four different exceptions to its threads: - hypervisor exception, - O/S exception - Event-Based Branch (EBB) - msgsnd (doorbell). Each exception has a state independent from the others called a Thread Interrupt Management context. This context is a set of registers which lets the thread handle priority management and interrupt acknowledgment among other things. The most important ones being : - Interrupt Priority Register (PIPR) - Interrupt Pending Buffer (IPB) - Current Processor Priority (CPPR) - Notification Source Register (NSR) These registers are accessible through a specific MMIO region, called the Thread Interrupt Management Area (TIMA), four aligned pages, each exposing a different view of the registers. First page (page address ending in 0b00) gives access to the entire context and is reserved for the ring 0 view for the physical thread context. The second (page address ending in 0b01) is for the hypervisor, ring 1 view. The third (page address ending in 0b10) is for the operating system, ring 2 view. The fourth (page address ending in 0b11) is for user level, ring 3 view. The thread interrupt context is modeled with a XiveTCTX object containing the values of the different exception registers. The TIMA region is mapped at the same address for each CPU. Signed-off-by: Cédric Le Goater <clg@kaod.org> Reviewed-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2018-12-09 22:45:53 +03:00
#define TM_QW0W2_VU PPC_BIT32(0)
#define TM_QW0W2_LOGIC_SERV PPC_BITMASK32(1, 31) /* XX 2,31 ? */
#define TM_QW1W2_VO PPC_BIT32(0)
#define TM_QW1W2_OS_CAM PPC_BITMASK32(8, 31)
#define TM_QW2W2_VP PPC_BIT32(0)
#define TM_QW2W2_POOL_CAM PPC_BITMASK32(8, 31)
#define TM_QW3W2_VT PPC_BIT32(0)
#define TM_QW3W2_LP PPC_BIT32(6)
#define TM_QW3W2_LE PPC_BIT32(7)
#define TM_QW3W2_T PPC_BIT32(31)
/*
* In addition to normal loads to "peek" and writes (only when invalid)
* using 4 and 8 bytes accesses, the above registers support these
* "special" byte operations:
*
* - Byte load from QW0[NSR] - User level NSR (EBB)
* - Byte store to QW0[NSR] - User level NSR (EBB)
* - Byte load/store to QW1[CPPR] and QW3[CPPR] - CPPR access
* - Byte load from QW3[TM_WORD2] - Read VT||00000||LP||LE on thrd 0
* otherwise VT||0000000
* - Byte store to QW3[TM_WORD2] - Set VT bit (and LP/LE if present)
*
* Then we have all these "special" CI ops at these offset that trigger
* all sorts of side effects:
*/
#define TM_SPC_ACK_EBB 0x800 /* Load8 ack EBB to reg*/
#define TM_SPC_ACK_OS_REG 0x810 /* Load16 ack OS irq to reg */
#define TM_SPC_PUSH_USR_CTX 0x808 /* Store32 Push/Validate user context */
#define TM_SPC_PULL_USR_CTX 0x808 /* Load32 Pull/Invalidate user
* context */
#define TM_SPC_SET_OS_PENDING 0x812 /* Store8 Set OS irq pending bit */
#define TM_SPC_PULL_OS_CTX 0x818 /* Load32/Load64 Pull/Invalidate OS
* context to reg */
#define TM_SPC_PULL_POOL_CTX 0x828 /* Load32/Load64 Pull/Invalidate Pool
* context to reg*/
#define TM_SPC_ACK_HV_REG 0x830 /* Load16 ack HV irq to reg */
#define TM_SPC_PULL_USR_CTX_OL 0xc08 /* Store8 Pull/Inval usr ctx to odd
* line */
#define TM_SPC_ACK_OS_EL 0xc10 /* Store8 ack OS irq to even line */
#define TM_SPC_ACK_HV_POOL_EL 0xc20 /* Store8 ack HV evt pool to even
* line */
#define TM_SPC_ACK_HV_EL 0xc30 /* Store8 ack HV irq to even line */
/* XXX more... */
/* NSR fields for the various QW ack types */
#define TM_QW0_NSR_EB PPC_BIT8(0)
#define TM_QW1_NSR_EO PPC_BIT8(0)
#define TM_QW3_NSR_HE PPC_BITMASK8(0, 1)
#define TM_QW3_NSR_HE_NONE 0
#define TM_QW3_NSR_HE_POOL 1
#define TM_QW3_NSR_HE_PHYS 2
#define TM_QW3_NSR_HE_LSI 3
#define TM_QW3_NSR_I PPC_BIT8(2)
#define TM_QW3_NSR_GRP_LVL PPC_BIT8(3, 7)
/*
* EAS (Event Assignment Structure)
*
* One per interrupt source. Targets an interrupt to a given Event
* Notification Descriptor (END) and provides the corresponding
* logical interrupt number (END data)
*/
typedef struct XiveEAS {
/*
* Use a single 64-bit definition to make it easier to perform
* atomic updates
*/
uint64_t w;
#define EAS_VALID PPC_BIT(0)
#define EAS_END_BLOCK PPC_BITMASK(4, 7) /* Destination END block# */
#define EAS_END_INDEX PPC_BITMASK(8, 31) /* Destination END index */
#define EAS_MASKED PPC_BIT(32) /* Masked */
#define EAS_END_DATA PPC_BITMASK(33, 63) /* Data written to the END */
} XiveEAS;
#define xive_eas_is_valid(eas) (be64_to_cpu((eas)->w) & EAS_VALID)
#define xive_eas_is_masked(eas) (be64_to_cpu((eas)->w) & EAS_MASKED)
void xive_eas_pic_print_info(XiveEAS *eas, uint32_t lisn, Monitor *mon);
static inline uint64_t xive_get_field64(uint64_t mask, uint64_t word)
{
return (be64_to_cpu(word) & mask) >> ctz64(mask);
}
static inline uint64_t xive_set_field64(uint64_t mask, uint64_t word,
uint64_t value)
{
uint64_t tmp =
(be64_to_cpu(word) & ~mask) | ((value << ctz64(mask)) & mask);
return cpu_to_be64(tmp);
}
static inline uint32_t xive_get_field32(uint32_t mask, uint32_t word)
{
return (be32_to_cpu(word) & mask) >> ctz32(mask);
}
static inline uint32_t xive_set_field32(uint32_t mask, uint32_t word,
uint32_t value)
{
uint32_t tmp =
(be32_to_cpu(word) & ~mask) | ((value << ctz32(mask)) & mask);
return cpu_to_be32(tmp);
}
/* Event Notification Descriptor (END) */
typedef struct XiveEND {
uint32_t w0;
#define END_W0_VALID PPC_BIT32(0) /* "v" bit */
#define END_W0_ENQUEUE PPC_BIT32(1) /* "q" bit */
#define END_W0_UCOND_NOTIFY PPC_BIT32(2) /* "n" bit */
#define END_W0_BACKLOG PPC_BIT32(3) /* "b" bit */
#define END_W0_PRECL_ESC_CTL PPC_BIT32(4) /* "p" bit */
#define END_W0_ESCALATE_CTL PPC_BIT32(5) /* "e" bit */
#define END_W0_UNCOND_ESCALATE PPC_BIT32(6) /* "u" bit - DD2.0 */
#define END_W0_SILENT_ESCALATE PPC_BIT32(7) /* "s" bit - DD2.0 */
#define END_W0_QSIZE PPC_BITMASK32(12, 15)
#define END_W0_SW0 PPC_BIT32(16)
#define END_W0_FIRMWARE END_W0_SW0 /* Owned by FW */
#define END_QSIZE_4K 0
#define END_QSIZE_64K 4
#define END_W0_HWDEP PPC_BITMASK32(24, 31)
uint32_t w1;
#define END_W1_ESn PPC_BITMASK32(0, 1)
#define END_W1_ESn_P PPC_BIT32(0)
#define END_W1_ESn_Q PPC_BIT32(1)
#define END_W1_ESe PPC_BITMASK32(2, 3)
#define END_W1_ESe_P PPC_BIT32(2)
#define END_W1_ESe_Q PPC_BIT32(3)
#define END_W1_GENERATION PPC_BIT32(9)
#define END_W1_PAGE_OFF PPC_BITMASK32(10, 31)
uint32_t w2;
#define END_W2_MIGRATION_REG PPC_BITMASK32(0, 3)
#define END_W2_OP_DESC_HI PPC_BITMASK32(4, 31)
uint32_t w3;
#define END_W3_OP_DESC_LO PPC_BITMASK32(0, 31)
uint32_t w4;
#define END_W4_ESC_END_BLOCK PPC_BITMASK32(4, 7)
#define END_W4_ESC_END_INDEX PPC_BITMASK32(8, 31)
uint32_t w5;
#define END_W5_ESC_END_DATA PPC_BITMASK32(1, 31)
uint32_t w6;
#define END_W6_FORMAT_BIT PPC_BIT32(8)
#define END_W6_NVT_BLOCK PPC_BITMASK32(9, 12)
#define END_W6_NVT_INDEX PPC_BITMASK32(13, 31)
uint32_t w7;
#define END_W7_F0_IGNORE PPC_BIT32(0)
#define END_W7_F0_BLK_GROUPING PPC_BIT32(1)
#define END_W7_F0_PRIORITY PPC_BITMASK32(8, 15)
#define END_W7_F1_WAKEZ PPC_BIT32(0)
#define END_W7_F1_LOG_SERVER_ID PPC_BITMASK32(1, 31)
} XiveEND;
#define xive_end_is_valid(end) (be32_to_cpu((end)->w0) & END_W0_VALID)
#define xive_end_is_enqueue(end) (be32_to_cpu((end)->w0) & END_W0_ENQUEUE)
#define xive_end_is_notify(end) (be32_to_cpu((end)->w0) & END_W0_UCOND_NOTIFY)
#define xive_end_is_backlog(end) (be32_to_cpu((end)->w0) & END_W0_BACKLOG)
#define xive_end_is_escalate(end) (be32_to_cpu((end)->w0) & END_W0_ESCALATE_CTL)
#define xive_end_is_uncond_escalation(end) \
(be32_to_cpu((end)->w0) & END_W0_UNCOND_ESCALATE)
#define xive_end_is_silent_escalation(end) \
(be32_to_cpu((end)->w0) & END_W0_SILENT_ESCALATE)
static inline uint64_t xive_end_qaddr(XiveEND *end)
{
return ((uint64_t) be32_to_cpu(end->w2) & 0x0fffffff) << 32 |
be32_to_cpu(end->w3);
}
void xive_end_pic_print_info(XiveEND *end, uint32_t end_idx, Monitor *mon);
void xive_end_queue_pic_print_info(XiveEND *end, uint32_t width, Monitor *mon);
void xive_end_eas_pic_print_info(XiveEND *end, uint32_t end_idx, Monitor *mon);
/* Notification Virtual Target (NVT) */
typedef struct XiveNVT {
uint32_t w0;
#define NVT_W0_VALID PPC_BIT32(0)
uint32_t w1;
#define NVT_W1_EQ_BLOCK PPC_BITMASK32(0, 3)
#define NVT_W1_EQ_INDEX PPC_BITMASK32(4, 31)
uint32_t w2;
uint32_t w3;
uint32_t w4;
#define NVT_W4_IPB PPC_BITMASK32(16, 23)
uint32_t w5;
uint32_t w6;
uint32_t w7;
uint32_t w8;
#define NVT_W8_GRP_VALID PPC_BIT32(0)
uint32_t w9;
uint32_t wa;
uint32_t wb;
uint32_t wc;
uint32_t wd;
uint32_t we;
uint32_t wf;
} XiveNVT;
#define xive_nvt_is_valid(nvt) (be32_to_cpu((nvt)->w0) & NVT_W0_VALID)
/*
* The VP number space in a block is defined by the END_W6_NVT_INDEX
* field of the XIVE END
*/
#define XIVE_NVT_SHIFT 19
#define XIVE_NVT_COUNT (1 << XIVE_NVT_SHIFT)
static inline uint32_t xive_nvt_cam_line(uint8_t nvt_blk, uint32_t nvt_idx)
{
return (nvt_blk << XIVE_NVT_SHIFT) | nvt_idx;
}
static inline uint32_t xive_nvt_idx(uint32_t cam_line)
{
return cam_line & ((1 << XIVE_NVT_SHIFT) - 1);
}
static inline uint32_t xive_nvt_blk(uint32_t cam_line)
{
return (cam_line >> XIVE_NVT_SHIFT) & 0xf;
}
#endif /* PPC_XIVE_REGS_H */