/* $OpenBSD: ahci.c,v 1.147 2009/02/16 21:19:07 miod Exp $ */ /* * Copyright (c) 2006 David Gwynne * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* change to AHCI_DEBUG for dmesg spam */ #define NO_AHCI_DEBUG #ifdef AHCI_DEBUG #define DPRINTF(m, f...) do { if ((ahcidebug & (m)) == (m)) printf(f); } \ while (0) #define AHCI_D_TIMEOUT 0x00 #define AHCI_D_VERBOSE 0x01 #define AHCI_D_INTR 0x02 #define AHCI_D_XFER 0x08 int ahcidebug = AHCI_D_VERBOSE; #else #define DPRINTF(m, f...) #endif #define AHCI_PCI_BAR 0x24 #define AHCI_PCI_ATI_SB600_MAGIC 0x40 #define AHCI_PCI_ATI_SB600_LOCKED 0x01 #define AHCI_PCI_INTERFACE 0x01 #define AHCI_REG_CAP 0x000 /* HBA Capabilities */ #define AHCI_REG_CAP_NP(_r) (((_r) & 0x1f)+1) /* Number of Ports */ #define AHCI_REG_CAP_SXS (1<<5) /* External SATA */ #define AHCI_REG_CAP_EMS (1<<6) /* Enclosure Mgmt */ #define AHCI_REG_CAP_CCCS (1<<7) /* Cmd Coalescing */ #define AHCI_REG_CAP_NCS(_r) ((((_r) & 0x1f00)>>8)+1) /* NCmds*/ #define AHCI_REG_CAP_PSC (1<<13) /* Partial State Capable */ #define AHCI_REG_CAP_SSC (1<<14) /* Slumber State Capable */ #define AHCI_REG_CAP_PMD (1<<15) /* PIO Multiple DRQ Block */ #define AHCI_REG_CAP_FBSS (1<<16) /* FIS-Based Switching */ #define AHCI_REG_CAP_SPM (1<<17) /* Port Multiplier */ #define AHCI_REG_CAP_SAM (1<<18) /* AHCI Only mode */ #define AHCI_REG_CAP_SNZO (1<<19) /* Non Zero DMA Offsets */ #define AHCI_REG_CAP_ISS (0xf<<20) /* Interface Speed Support */ #define AHCI_REG_CAP_ISS_G1 (0x1<<20) /* Gen 1 (1.5 Gbps) */ #define AHCI_REG_CAP_ISS_G1_2 (0x2<<20) /* Gen 1 and 2 (3 Gbps) */ #define AHCI_REG_CAP_SCLO (1<<24) /* Cmd List Override */ #define AHCI_REG_CAP_SAL (1<<25) /* Activity LED */ #define AHCI_REG_CAP_SALP (1<<26) /* Aggressive Link Pwr Mgmt */ #define AHCI_REG_CAP_SSS (1<<27) /* Staggered Spinup */ #define AHCI_REG_CAP_SMPS (1<<28) /* Mech Presence Switch */ #define AHCI_REG_CAP_SSNTF (1<<29) /* SNotification Register */ #define AHCI_REG_CAP_SNCQ (1<<30) /* Native Cmd Queuing */ #define AHCI_REG_CAP_S64A (1<<31) /* 64bit Addressing */ #define AHCI_FMT_CAP "\020" "\040S64A" "\037NCQ" "\036SSNTF" \ "\035SMPS" "\034SSS" "\033SALP" "\032SAL" \ "\031SCLO" "\024SNZO" "\023SAM" "\022SPM" \ "\021FBSS" "\020PMD" "\017SSC" "\016PSC" \ "\010CCCS" "\007EMS" "\006SXS" #define AHCI_REG_GHC 0x004 /* Global HBA Control */ #define AHCI_REG_GHC_HR (1<<0) /* HBA Reset */ #define AHCI_REG_GHC_IE (1<<1) /* Interrupt Enable */ #define AHCI_REG_GHC_MRSM (1<<2) /* MSI Revert to Single Msg */ #define AHCI_REG_GHC_AE (1<<31) /* AHCI Enable */ #define AHCI_FMT_GHC "\020" "\040AE" "\003MRSM" "\002IE" "\001HR" #define AHCI_REG_IS 0x008 /* Interrupt Status */ #define AHCI_REG_PI 0x00c /* Ports Implemented */ #define AHCI_REG_VS 0x010 /* AHCI Version */ #define AHCI_REG_VS_0_95 0x00000905 /* 0.95 */ #define AHCI_REG_VS_1_0 0x00010000 /* 1.0 */ #define AHCI_REG_VS_1_1 0x00010100 /* 1.1 */ #define AHCI_REG_VS_1_2 0x00010200 /* 1.2 */ #define AHCI_REG_CCC_CTL 0x014 /* Coalescing Control */ #define AHCI_REG_CCC_CTL_INT(_r) (((_r) & 0xf8) >> 3) /* CCC INT slot */ #define AHCI_REG_CCC_PORTS 0x018 /* Coalescing Ports */ #define AHCI_REG_EM_LOC 0x01c /* Enclosure Mgmt Location */ #define AHCI_REG_EM_CTL 0x020 /* Enclosure Mgmt Control */ #define AHCI_PORT_REGION(_p) (0x100 + ((_p) * 0x80)) #define AHCI_PORT_SIZE 0x80 #define AHCI_PREG_CLB 0x00 /* Cmd List Base Addr */ #define AHCI_PREG_CLBU 0x04 /* Cmd List Base Hi Addr */ #define AHCI_PREG_FB 0x08 /* FIS Base Addr */ #define AHCI_PREG_FBU 0x0c /* FIS Base Hi Addr */ #define AHCI_PREG_IS 0x10 /* Interrupt Status */ #define AHCI_PREG_IS_DHRS (1<<0) /* Device to Host FIS */ #define AHCI_PREG_IS_PSS (1<<1) /* PIO Setup FIS */ #define AHCI_PREG_IS_DSS (1<<2) /* DMA Setup FIS */ #define AHCI_PREG_IS_SDBS (1<<3) /* Set Device Bits FIS */ #define AHCI_PREG_IS_UFS (1<<4) /* Unknown FIS */ #define AHCI_PREG_IS_DPS (1<<5) /* Descriptor Processed */ #define AHCI_PREG_IS_PCS (1<<6) /* Port Change */ #define AHCI_PREG_IS_DMPS (1<<7) /* Device Mechanical Presence */ #define AHCI_PREG_IS_PRCS (1<<22) /* PhyRdy Change */ #define AHCI_PREG_IS_IPMS (1<<23) /* Incorrect Port Multiplier */ #define AHCI_PREG_IS_OFS (1<<24) /* Overflow */ #define AHCI_PREG_IS_INFS (1<<26) /* Interface Non-fatal Error */ #define AHCI_PREG_IS_IFS (1<<27) /* Interface Fatal Error */ #define AHCI_PREG_IS_HBDS (1<<28) /* Host Bus Data Error */ #define AHCI_PREG_IS_HBFS (1<<29) /* Host Bus Fatal Error */ #define AHCI_PREG_IS_TFES (1<<30) /* Task File Error */ #define AHCI_PREG_IS_CPDS (1<<31) /* Cold Presence Detect */ #define AHCI_PFMT_IS "\20" "\040CPDS" "\037TFES" "\036HBFS" \ "\035HBDS" "\034IFS" "\033INFS" "\031OFS" \ "\030IPMS" "\027PRCS" "\010DMPS" "\006DPS" \ "\007PCS" "\005UFS" "\004SDBS" "\003DSS" \ "\002PSS" "\001DHRS" #define AHCI_PREG_IE 0x14 /* Interrupt Enable */ #define AHCI_PREG_IE_DHRE (1<<0) /* Device to Host FIS */ #define AHCI_PREG_IE_PSE (1<<1) /* PIO Setup FIS */ #define AHCI_PREG_IE_DSE (1<<2) /* DMA Setup FIS */ #define AHCI_PREG_IE_SDBE (1<<3) /* Set Device Bits FIS */ #define AHCI_PREG_IE_UFE (1<<4) /* Unknown FIS */ #define AHCI_PREG_IE_DPE (1<<5) /* Descriptor Processed */ #define AHCI_PREG_IE_PCE (1<<6) /* Port Change */ #define AHCI_PREG_IE_DMPE (1<<7) /* Device Mechanical Presence */ #define AHCI_PREG_IE_PRCE (1<<22) /* PhyRdy Change */ #define AHCI_PREG_IE_IPME (1<<23) /* Incorrect Port Multiplier */ #define AHCI_PREG_IE_OFE (1<<24) /* Overflow */ #define AHCI_PREG_IE_INFE (1<<26) /* Interface Non-fatal Error */ #define AHCI_PREG_IE_IFE (1<<27) /* Interface Fatal Error */ #define AHCI_PREG_IE_HBDE (1<<28) /* Host Bus Data Error */ #define AHCI_PREG_IE_HBFE (1<<29) /* Host Bus Fatal Error */ #define AHCI_PREG_IE_TFEE (1<<30) /* Task File Error */ #define AHCI_PREG_IE_CPDE (1<<31) /* Cold Presence Detect */ #define AHCI_PFMT_IE "\20" "\040CPDE" "\037TFEE" "\036HBFE" \ "\035HBDE" "\034IFE" "\033INFE" "\031OFE" \ "\030IPME" "\027PRCE" "\010DMPE" "\007PCE" \ "\006DPE" "\005UFE" "\004SDBE" "\003DSE" \ "\002PSE" "\001DHRE" #define AHCI_PREG_CMD 0x18 /* Command and Status */ #define AHCI_PREG_CMD_ST (1<<0) /* Start */ #define AHCI_PREG_CMD_SUD (1<<1) /* Spin Up Device */ #define AHCI_PREG_CMD_POD (1<<2) /* Power On Device */ #define AHCI_PREG_CMD_CLO (1<<3) /* Command List Override */ #define AHCI_PREG_CMD_FRE (1<<4) /* FIS Receive Enable */ #define AHCI_PREG_CMD_CCS(_r) (((_r) >> 8) & 0x1f) /* Curr CmdSlot# */ #define AHCI_PREG_CMD_MPSS (1<<13) /* Mech Presence State */ #define AHCI_PREG_CMD_FR (1<<14) /* FIS Receive Running */ #define AHCI_PREG_CMD_CR (1<<15) /* Command List Running */ #define AHCI_PREG_CMD_CPS (1<<16) /* Cold Presence State */ #define AHCI_PREG_CMD_PMA (1<<17) /* Port Multiplier Attached */ #define AHCI_PREG_CMD_HPCP (1<<18) /* Hot Plug Capable */ #define AHCI_PREG_CMD_MPSP (1<<19) /* Mech Presence Switch */ #define AHCI_PREG_CMD_CPD (1<<20) /* Cold Presence Detection */ #define AHCI_PREG_CMD_ESP (1<<21) /* External SATA Port */ #define AHCI_PREG_CMD_ATAPI (1<<24) /* Device is ATAPI */ #define AHCI_PREG_CMD_DLAE (1<<25) /* Drv LED on ATAPI Enable */ #define AHCI_PREG_CMD_ALPE (1<<26) /* Aggro Pwr Mgmt Enable */ #define AHCI_PREG_CMD_ASP (1<<27) /* Aggro Slumber/Partial */ #define AHCI_PREG_CMD_ICC 0xf0000000 /* Interface Comm Ctrl */ #define AHCI_PREG_CMD_ICC_SLUMBER 0x60000000 #define AHCI_PREG_CMD_ICC_PARTIAL 0x20000000 #define AHCI_PREG_CMD_ICC_ACTIVE 0x10000000 #define AHCI_PREG_CMD_ICC_IDLE 0x00000000 #define AHCI_PFMT_CMD "\020" "\034ASP" "\033ALPE" "\032DLAE" \ "\031ATAPI" "\026ESP" "\025CPD" "\024MPSP" \ "\023HPCP" "\022PMA" "\021CPS" "\020CR" \ "\017FR" "\016MPSS" "\005FRE" "\004CLO" \ "\003POD" "\002SUD" "\001ST" #define AHCI_PREG_TFD 0x20 /* Task File Data*/ #define AHCI_PREG_TFD_STS 0xff #define AHCI_PREG_TFD_STS_ERR (1<<0) #define AHCI_PREG_TFD_STS_DRQ (1<<3) #define AHCI_PREG_TFD_STS_BSY (1<<7) #define AHCI_PREG_TFD_ERR 0xff00 #define AHCI_PFMT_TFD_STS "\20" "\010BSY" "\004DRQ" "\001ERR" #define AHCI_PREG_SIG 0x24 /* Signature */ #define AHCI_PREG_SSTS 0x28 /* SATA Status */ #define AHCI_PREG_SSTS_DET 0xf /* Device Detection */ #define AHCI_PREG_SSTS_DET_NONE 0x0 #define AHCI_PREG_SSTS_DET_DEV_NE 0x1 #define AHCI_PREG_SSTS_DET_DEV 0x3 #define AHCI_PREG_SSTS_DET_PHYOFFLINE 0x4 #define AHCI_PREG_SSTS_SPD 0xf0 /* Current Interface Speed */ #define AHCI_PREG_SSTS_SPD_NONE 0x00 #define AHCI_PREG_SSTS_SPD_GEN1 0x10 #define AHCI_PREG_SSTS_SPD_GEN2 0x20 #define AHCI_PREG_SSTS_IPM 0xf00 /* Interface Power Management */ #define AHCI_PREG_SSTS_IPM_NONE 0x000 #define AHCI_PREG_SSTS_IPM_ACTIVE 0x100 #define AHCI_PREG_SSTS_IPM_PARTIAL 0x200 #define AHCI_PREG_SSTS_IPM_SLUMBER 0x600 #define AHCI_PREG_SCTL 0x2c /* SATA Control */ #define AHCI_PREG_SCTL_DET 0xf /* Device Detection */ #define AHCI_PREG_SCTL_DET_NONE 0x0 #define AHCI_PREG_SCTL_DET_INIT 0x1 #define AHCI_PREG_SCTL_DET_DISABLE 0x4 #define AHCI_PREG_SCTL_SPD 0xf0 /* Speed Allowed */ #define AHCI_PREG_SCTL_SPD_ANY 0x00 #define AHCI_PREG_SCTL_SPD_GEN1 0x10 #define AHCI_PREG_SCTL_SPD_GEN2 0x20 #define AHCI_PREG_SCTL_IPM 0xf00 /* Interface Power Management */ #define AHCI_PREG_SCTL_IPM_NONE 0x000 #define AHCI_PREG_SCTL_IPM_NOPARTIAL 0x100 #define AHCI_PREG_SCTL_IPM_NOSLUMBER 0x200 #define AHCI_PREG_SCTL_IPM_DISABLED 0x300 #define AHCI_PREG_SERR 0x30 /* SATA Error */ #define AHCI_PREG_SERR_ERR(_r) ((_r) & 0xffff) #define AHCI_PREG_SERR_ERR_I (1<<0) /* Recovered Data Integrity */ #define AHCI_PREG_SERR_ERR_M (1<<1) /* Recovered Communications */ #define AHCI_PREG_SERR_ERR_T (1<<8) /* Transient Data Integrity */ #define AHCI_PREG_SERR_ERR_C (1<<9) /* Persistent Comm/Data */ #define AHCI_PREG_SERR_ERR_P (1<<10) /* Protocol */ #define AHCI_PREG_SERR_ERR_E (1<<11) /* Internal */ #define AHCI_PFMT_SERR_ERR "\020" "\014E" "\013P" "\012C" "\011T" "\002M" \ "\001I" #define AHCI_PREG_SERR_DIAG(_r) (((_r) >> 16) & 0xffff) #define AHCI_PREG_SERR_DIAG_N (1<<0) /* PhyRdy Change */ #define AHCI_PREG_SERR_DIAG_I (1<<1) /* Phy Internal Error */ #define AHCI_PREG_SERR_DIAG_W (1<<2) /* Comm Wake */ #define AHCI_PREG_SERR_DIAG_B (1<<3) /* 10B to 8B Decode Error */ #define AHCI_PREG_SERR_DIAG_D (1<<4) /* Disparity Error */ #define AHCI_PREG_SERR_DIAG_C (1<<5) /* CRC Error */ #define AHCI_PREG_SERR_DIAG_H (1<<6) /* Handshake Error */ #define AHCI_PREG_SERR_DIAG_S (1<<7) /* Link Sequence Error */ #define AHCI_PREG_SERR_DIAG_T (1<<8) /* Transport State Trans Err */ #define AHCI_PREG_SERR_DIAG_F (1<<9) /* Unknown FIS Type */ #define AHCI_PREG_SERR_DIAG_X (1<<10) /* Exchanged */ #define AHCI_PFMT_SERR_DIAG "\020" "\013X" "\012F" "\011T" "\010S" "\007H" \ "\006C" "\005D" "\004B" "\003W" "\002I" \ "\001N" #define AHCI_PREG_SACT 0x34 /* SATA Active */ #define AHCI_PREG_CI 0x38 /* Command Issue */ #define AHCI_PREG_CI_ALL_SLOTS 0xffffffff #define AHCI_PREG_SNTF 0x3c /* SNotification */ struct ahci_cmd_hdr { u_int16_t flags; #define AHCI_CMD_LIST_FLAG_CFL 0x001f /* Command FIS Length */ #define AHCI_CMD_LIST_FLAG_A (1<<5) /* ATAPI */ #define AHCI_CMD_LIST_FLAG_W (1<<6) /* Write */ #define AHCI_CMD_LIST_FLAG_P (1<<7) /* Prefetchable */ #define AHCI_CMD_LIST_FLAG_R (1<<8) /* Reset */ #define AHCI_CMD_LIST_FLAG_B (1<<9) /* BIST */ #define AHCI_CMD_LIST_FLAG_C (1<<10) /* Clear Busy upon R_OK */ #define AHCI_CMD_LIST_FLAG_PMP 0xf000 /* Port Multiplier Port */ u_int16_t prdtl; /* sgl len */ u_int32_t prdbc; /* transferred byte count */ u_int32_t ctba_lo; u_int32_t ctba_hi; u_int32_t reserved[4]; } __packed; struct ahci_rfis { u_int8_t dsfis[28]; u_int8_t reserved1[4]; u_int8_t psfis[24]; u_int8_t reserved2[8]; u_int8_t rfis[24]; u_int8_t reserved3[4]; u_int8_t sdbfis[4]; u_int8_t ufis[64]; u_int8_t reserved4[96]; } __packed; struct ahci_prdt { u_int32_t dba_lo; u_int32_t dba_hi; u_int32_t reserved; u_int32_t flags; #define AHCI_PRDT_FLAG_INTR (1<<31) /* interrupt on completion */ } __packed; /* this makes ahci_cmd_table 512 bytes, supporting 128-byte alignment */ #define AHCI_MAX_PRDT 24 struct ahci_cmd_table { u_int8_t cfis[64]; /* Command FIS */ u_int8_t acmd[16]; /* ATAPI Command */ u_int8_t reserved[48]; struct ahci_prdt prdt[AHCI_MAX_PRDT]; } __packed; #define AHCI_MAX_PORTS 32 struct ahci_dmamem { bus_dmamap_t adm_map; bus_dma_segment_t adm_seg; size_t adm_size; caddr_t adm_kva; }; #define AHCI_DMA_MAP(_adm) ((_adm)->adm_map) #define AHCI_DMA_DVA(_adm) ((_adm)->adm_map->dm_segs[0].ds_addr) #define AHCI_DMA_KVA(_adm) ((void *)(_adm)->adm_kva) struct ahci_softc; struct ahci_port; struct ahci_ccb { /* ATA xfer associated with this CCB. Must be 1st struct member. */ struct ata_xfer ccb_xa; int ccb_slot; struct ahci_port *ccb_port; bus_dmamap_t ccb_dmamap; struct ahci_cmd_hdr *ccb_cmd_hdr; struct ahci_cmd_table *ccb_cmd_table; void (*ccb_done)(struct ahci_ccb *); TAILQ_ENTRY(ahci_ccb) ccb_entry; }; struct ahci_port { struct ahci_softc *ap_sc; bus_space_handle_t ap_ioh; #ifdef AHCI_COALESCE int ap_num; #endif struct ahci_rfis *ap_rfis; struct ahci_dmamem *ap_dmamem_rfis; struct ahci_dmamem *ap_dmamem_cmd_list; struct ahci_dmamem *ap_dmamem_cmd_table; volatile u_int32_t ap_active; volatile u_int32_t ap_active_cnt; volatile u_int32_t ap_sactive; struct ahci_ccb *ap_ccbs; TAILQ_HEAD(, ahci_ccb) ap_ccb_free; TAILQ_HEAD(, ahci_ccb) ap_ccb_pending; struct mutex ap_ccb_mtx; u_int32_t ap_state; #define AP_S_NORMAL 0 #define AP_S_FATAL_ERROR 1 /* For error recovery. */ #ifdef DIAGNOSTIC int ap_err_busy; #endif u_int32_t ap_err_saved_sactive; u_int32_t ap_err_saved_active; u_int32_t ap_err_saved_active_cnt; u_int8_t ap_err_scratch[512]; #ifdef AHCI_DEBUG char ap_name[16]; #define PORTNAME(_ap) ((_ap)->ap_name) #else #define PORTNAME(_ap) DEVNAME((_ap)->ap_sc) #endif }; struct ahci_softc { struct device sc_dev; void *sc_ih; pci_chipset_tag_t sc_pc; bus_space_tag_t sc_iot; bus_space_handle_t sc_ioh; bus_size_t sc_ios; bus_dma_tag_t sc_dmat; int sc_flags; #define AHCI_F_NO_NCQ (1<<0) #define AHCI_F_IGN_FR (1<<1) u_int sc_ncmds; struct ahci_port *sc_ports[AHCI_MAX_PORTS]; struct atascsi *sc_atascsi; #ifdef AHCI_COALESCE u_int32_t sc_ccc_mask; u_int32_t sc_ccc_ports; u_int32_t sc_ccc_ports_cur; #endif }; #define DEVNAME(_s) ((_s)->sc_dev.dv_xname) struct ahci_device { pci_vendor_id_t ad_vendor; pci_product_id_t ad_product; int (*ad_match)(struct pci_attach_args *); int (*ad_attach)(struct ahci_softc *, struct pci_attach_args *); }; const struct ahci_device *ahci_lookup_device(struct pci_attach_args *); int ahci_no_match(struct pci_attach_args *); int ahci_vt8251_attach(struct ahci_softc *, struct pci_attach_args *); int ahci_ati_sb600_attach(struct ahci_softc *, struct pci_attach_args *); int ahci_nvidia_mcp_attach(struct ahci_softc *, struct pci_attach_args *); static const struct ahci_device ahci_devices[] = { { PCI_VENDOR_VIATECH, PCI_PRODUCT_VIATECH_VT8251_SATA, ahci_no_match, ahci_vt8251_attach }, { PCI_VENDOR_ATI, PCI_PRODUCT_ATI_SB600_SATA, NULL, ahci_ati_sb600_attach }, { PCI_VENDOR_NVIDIA, PCI_PRODUCT_NVIDIA_MCP65_AHCI_2, NULL, ahci_nvidia_mcp_attach }, { PCI_VENDOR_NVIDIA, PCI_PRODUCT_NVIDIA_MCP67_AHCI_1, NULL, ahci_nvidia_mcp_attach }, { PCI_VENDOR_NVIDIA, PCI_PRODUCT_NVIDIA_MCP77_AHCI_5, NULL, ahci_nvidia_mcp_attach } }; int ahci_pci_match(struct device *, void *, void *); void ahci_pci_attach(struct device *, struct device *, void *); int ahci_pci_detach(struct device *, int); struct cfattach ahci_pci_ca = { sizeof(struct ahci_softc), ahci_pci_match, ahci_pci_attach, ahci_pci_detach }; struct cfattach ahci_jmb_ca = { sizeof(struct ahci_softc), ahci_pci_match, ahci_pci_attach, ahci_pci_detach }; struct cfdriver ahci_cd = { NULL, "ahci", DV_DULL }; int ahci_map_regs(struct ahci_softc *, struct pci_attach_args *); void ahci_unmap_regs(struct ahci_softc *); int ahci_map_intr(struct ahci_softc *, struct pci_attach_args *, pci_intr_handle_t); void ahci_unmap_intr(struct ahci_softc *); int ahci_init(struct ahci_softc *); int ahci_port_alloc(struct ahci_softc *, u_int); void ahci_port_free(struct ahci_softc *, u_int); int ahci_port_start(struct ahci_port *, int); int ahci_port_stop(struct ahci_port *, int); int ahci_port_clo(struct ahci_port *); int ahci_port_softreset(struct ahci_port *); int ahci_port_portreset(struct ahci_port *); int ahci_load_prdt(struct ahci_ccb *); void ahci_unload_prdt(struct ahci_ccb *); int ahci_poll(struct ahci_ccb *, int, void (*)(void *)); void ahci_start(struct ahci_ccb *); void ahci_issue_pending_ncq_commands(struct ahci_port *); void ahci_issue_pending_commands(struct ahci_port *, int); int ahci_intr(void *); u_int32_t ahci_port_intr(struct ahci_port *, u_int32_t); struct ahci_ccb *ahci_get_ccb(struct ahci_port *); void ahci_put_ccb(struct ahci_ccb *); struct ahci_ccb *ahci_get_err_ccb(struct ahci_port *); void ahci_put_err_ccb(struct ahci_ccb *); int ahci_port_read_ncq_error(struct ahci_port *, int *); struct ahci_dmamem *ahci_dmamem_alloc(struct ahci_softc *, size_t); void ahci_dmamem_free(struct ahci_softc *, struct ahci_dmamem *); u_int32_t ahci_read(struct ahci_softc *, bus_size_t); void ahci_write(struct ahci_softc *, bus_size_t, u_int32_t); int ahci_wait_ne(struct ahci_softc *, bus_size_t, u_int32_t, u_int32_t); u_int32_t ahci_pread(struct ahci_port *, bus_size_t); void ahci_pwrite(struct ahci_port *, bus_size_t, u_int32_t); int ahci_pwait_eq(struct ahci_port *, bus_size_t, u_int32_t, u_int32_t); /* Wait for all bits in _b to be cleared */ #define ahci_pwait_clr(_ap, _r, _b) ahci_pwait_eq((_ap), (_r), (_b), 0) /* Wait for all bits in _b to be set */ #define ahci_pwait_set(_ap, _r, _b) ahci_pwait_eq((_ap), (_r), (_b), (_b)) /* provide methods for atascsi to call */ int ahci_ata_probe(void *, int); void ahci_ata_free(void *, int); struct ata_xfer * ahci_ata_get_xfer(void *, int); void ahci_ata_put_xfer(struct ata_xfer *); int ahci_ata_cmd(struct ata_xfer *); struct atascsi_methods ahci_atascsi_methods = { ahci_ata_probe, ahci_ata_free, ahci_ata_get_xfer, ahci_ata_cmd }; /* ccb completions */ void ahci_ata_cmd_done(struct ahci_ccb *); void ahci_ata_cmd_timeout(void *); void ahci_empty_done(struct ahci_ccb *); const struct ahci_device * ahci_lookup_device(struct pci_attach_args *pa) { int i; const struct ahci_device *ad; for (i = 0; i < (sizeof(ahci_devices) / sizeof(ahci_devices[0])); i++) { ad = &ahci_devices[i]; if (ad->ad_vendor == PCI_VENDOR(pa->pa_id) && ad->ad_product == PCI_PRODUCT(pa->pa_id)) return (ad); } return (NULL); } int ahci_no_match(struct pci_attach_args *pa) { return (0); } int ahci_vt8251_attach(struct ahci_softc *sc, struct pci_attach_args *pa) { sc->sc_flags |= AHCI_F_NO_NCQ; return (0); } int ahci_ati_sb600_attach(struct ahci_softc *sc, struct pci_attach_args *pa) { pcireg_t magic; if (PCI_SUBCLASS(pa->pa_class) == PCI_SUBCLASS_MASS_STORAGE_IDE) { magic = pci_conf_read(pa->pa_pc, pa->pa_tag, AHCI_PCI_ATI_SB600_MAGIC); pci_conf_write(pa->pa_pc, pa->pa_tag, AHCI_PCI_ATI_SB600_MAGIC, magic | AHCI_PCI_ATI_SB600_LOCKED); pci_conf_write(pa->pa_pc, pa->pa_tag, PCI_CLASS_REG, PCI_CLASS_MASS_STORAGE << PCI_CLASS_SHIFT | PCI_SUBCLASS_MASS_STORAGE_SATA << PCI_SUBCLASS_SHIFT | AHCI_PCI_INTERFACE << PCI_INTERFACE_SHIFT | PCI_REVISION(pa->pa_class) << PCI_REVISION_SHIFT); pci_conf_write(pa->pa_pc, pa->pa_tag, AHCI_PCI_ATI_SB600_MAGIC, magic); } sc->sc_flags |= AHCI_F_IGN_FR; return (0); } int ahci_nvidia_mcp_attach(struct ahci_softc *sc, struct pci_attach_args *pa) { sc->sc_flags |= AHCI_F_IGN_FR; return (0); } int ahci_pci_match(struct device *parent, void *match, void *aux) { struct pci_attach_args *pa = aux; const struct ahci_device *ad; ad = ahci_lookup_device(pa); if (ad != NULL) { /* the device may need special checks to see if it matches */ if (ad->ad_match != NULL) return (ad->ad_match(pa)); return (2); /* match higher than pciide */ } if (PCI_CLASS(pa->pa_class) == PCI_CLASS_MASS_STORAGE && PCI_SUBCLASS(pa->pa_class) == PCI_SUBCLASS_MASS_STORAGE_SATA && PCI_INTERFACE(pa->pa_class) == AHCI_PCI_INTERFACE) return (2); return (0); } void ahci_pci_attach(struct device *parent, struct device *self, void *aux) { struct ahci_softc *sc = (struct ahci_softc *)self; struct pci_attach_args *pa = aux; struct atascsi_attach_args aaa; const struct ahci_device *ad; pci_intr_handle_t ih; u_int32_t cap, pi; int i; sc->sc_pc = pa->pa_pc; ad = ahci_lookup_device(pa); if (ad != NULL && ad->ad_attach != NULL) { if (ad->ad_attach(sc, pa) != 0) { /* error should be printed by ad_attach */ return; } } if (pci_intr_map(pa, &ih) != 0) { printf(": unable to map interrupt\n"); return; } printf(": %s,", pci_intr_string(pa->pa_pc, ih)); if (ahci_map_regs(sc, pa) != 0) { /* error already printed by ahci_map_regs */ return; } if (ahci_init(sc) != 0) { /* error already printed by ahci_init */ goto unmap; } if (ahci_map_intr(sc, pa, ih) != 0) { /* error already printed by ahci_map_intr */ goto unmap; } printf("\n"); sc->sc_dmat = pa->pa_dmat; cap = ahci_read(sc, AHCI_REG_CAP); sc->sc_ncmds = AHCI_REG_CAP_NCS(cap); #ifdef AHCI_DEBUG if (ahcidebug & AHCI_D_VERBOSE) { const char *gen; switch (cap & AHCI_REG_CAP_ISS) { case AHCI_REG_CAP_ISS_G1: gen = "1 (1.5Gbps)"; break; case AHCI_REG_CAP_ISS_G1_2: gen = "1 (1.5Gbps) and 2 (3Gbps)"; break; default: gen = "unknown"; break; } printf("%s: capabilities 0x%b, %d ports, %d cmds, gen %s\n", DEVNAME(sc), cap, AHCI_FMT_CAP, AHCI_REG_CAP_NP(cap), sc->sc_ncmds, gen); } #endif pi = ahci_read(sc, AHCI_REG_PI); DPRINTF(AHCI_D_VERBOSE, "%s: ports implemented: 0x%08x\n", DEVNAME(sc), pi); #ifdef AHCI_COALESCE /* Naive coalescing support - enable for all ports. */ if (cap & AHCI_REG_CAP_CCCS) { u_int16_t ccc_timeout = 20; u_int8_t ccc_numcomplete = 12; u_int32_t ccc_ctl; /* disable coalescing during reconfiguration. */ ccc_ctl = ahci_read(sc, AHCI_REG_CCC_CTL); ccc_ctl &= ~0x00000001; ahci_write(sc, AHCI_REG_CCC_CTL, ccc_ctl); sc->sc_ccc_mask = 1 << AHCI_REG_CCC_CTL_INT(ccc_ctl); if (pi & sc->sc_ccc_mask) { /* A conflict with the implemented port list? */ printf("%s: coalescing interrupt/implemented port list " "conflict, PI: %08x, ccc_mask: %08x\n", DEVNAME(sc), pi, sc->sc_ccc_mask); sc->sc_ccc_mask = 0; goto noccc; } /* ahci_port_start will enable each port when it starts. */ sc->sc_ccc_ports = pi; sc->sc_ccc_ports_cur = 0; /* program thresholds and enable overall coalescing. */ ccc_ctl &= ~0xffffff00; ccc_ctl |= (ccc_timeout << 16) | (ccc_numcomplete << 8); ahci_write(sc, AHCI_REG_CCC_CTL, ccc_ctl); ahci_write(sc, AHCI_REG_CCC_PORTS, 0); ahci_write(sc, AHCI_REG_CCC_CTL, ccc_ctl | 1); } noccc: #endif for (i = 0; i < AHCI_MAX_PORTS; i++) { if (!ISSET(pi, 1 << i)) { /* dont allocate stuff if the port isnt implemented */ continue; } if (ahci_port_alloc(sc, i) == ENOMEM) goto freeports; } bzero(&aaa, sizeof(aaa)); aaa.aaa_cookie = sc; aaa.aaa_methods = &ahci_atascsi_methods; aaa.aaa_minphys = NULL; aaa.aaa_nports = AHCI_MAX_PORTS; aaa.aaa_ncmds = sc->sc_ncmds; aaa.aaa_capability = ASAA_CAP_NEEDS_RESERVED; if (!(sc->sc_flags & AHCI_F_NO_NCQ) && (cap & AHCI_REG_CAP_SNCQ)) aaa.aaa_capability |= ASAA_CAP_NCQ; sc->sc_atascsi = atascsi_attach(&sc->sc_dev, &aaa); /* Enable interrupts */ ahci_write(sc, AHCI_REG_GHC, AHCI_REG_GHC_AE | AHCI_REG_GHC_IE); return; freeports: for (i = 0; i < AHCI_MAX_PORTS; i++) { if (sc->sc_ports[i] != NULL) ahci_port_free(sc, i); } unmap: /* Disable controller */ ahci_write(sc, AHCI_REG_GHC, 0); ahci_unmap_regs(sc); return; } int ahci_pci_detach(struct device *self, int flags) { struct ahci_softc *sc = (struct ahci_softc *)self; int rv, i; if (sc->sc_atascsi != NULL) { rv = atascsi_detach(sc->sc_atascsi, flags); if (rv != 0) return (rv); } for (i = 0; i < AHCI_MAX_PORTS; i++) { if (sc->sc_ports[i] != NULL) ahci_port_free(sc, i); } ahci_unmap_intr(sc); ahci_unmap_regs(sc); return (0); } int ahci_map_regs(struct ahci_softc *sc, struct pci_attach_args *pa) { pcireg_t maptype; maptype = pci_mapreg_type(pa->pa_pc, pa->pa_tag, AHCI_PCI_BAR); if (pci_mapreg_map(pa, AHCI_PCI_BAR, maptype, 0, &sc->sc_iot, &sc->sc_ioh, NULL, &sc->sc_ios, 0) != 0) { printf(" unable to map registers\n"); return (1); } return (0); } void ahci_unmap_regs(struct ahci_softc *sc) { bus_space_unmap(sc->sc_iot, sc->sc_ioh, sc->sc_ios); sc->sc_ios = 0; } int ahci_map_intr(struct ahci_softc *sc, struct pci_attach_args *pa, pci_intr_handle_t ih) { sc->sc_ih = pci_intr_establish(sc->sc_pc, ih, IPL_BIO, ahci_intr, sc, DEVNAME(sc)); if (sc->sc_ih == NULL) { printf("%s: unable to map interrupt\n", DEVNAME(sc)); return (1); } return (0); } void ahci_unmap_intr(struct ahci_softc *sc) { pci_intr_disestablish(sc->sc_pc, sc->sc_ih); } int ahci_init(struct ahci_softc *sc) { u_int32_t reg, cap, pi; const char *revision; DPRINTF(AHCI_D_VERBOSE, " GHC 0x%b", ahci_read(sc, AHCI_REG_GHC), AHCI_FMT_GHC); /* save BIOS initialised parameters, enable staggered spin up */ cap = ahci_read(sc, AHCI_REG_CAP); cap &= AHCI_REG_CAP_SMPS; cap |= AHCI_REG_CAP_SSS; pi = ahci_read(sc, AHCI_REG_PI); if (ISSET(AHCI_REG_GHC_AE, ahci_read(sc, AHCI_REG_GHC))) { /* reset the controller */ ahci_write(sc, AHCI_REG_GHC, AHCI_REG_GHC_HR); if (ahci_wait_ne(sc, AHCI_REG_GHC, AHCI_REG_GHC_HR, AHCI_REG_GHC_HR) != 0) { printf(" unable to reset controller\n"); return (1); } } /* enable ahci (global interrupts disabled) */ ahci_write(sc, AHCI_REG_GHC, AHCI_REG_GHC_AE); /* restore parameters */ ahci_write(sc, AHCI_REG_CAP, cap); ahci_write(sc, AHCI_REG_PI, pi); /* check the revision */ reg = ahci_read(sc, AHCI_REG_VS); switch (reg) { case AHCI_REG_VS_0_95: revision = "0.95"; break; case AHCI_REG_VS_1_0: revision = "1.0"; break; case AHCI_REG_VS_1_1: revision = "1.1"; break; case AHCI_REG_VS_1_2: revision = "1.2"; break; default: printf(" unsupported AHCI revision 0x%08x\n", reg); return (1); } printf(" AHCI %s", revision); return (0); } int ahci_port_alloc(struct ahci_softc *sc, u_int port) { struct ahci_port *ap; struct ahci_ccb *ccb; u_int64_t dva; u_int32_t cmd; struct ahci_cmd_hdr *hdr; struct ahci_cmd_table *table; int i, rc = ENOMEM; ap = malloc(sizeof(*ap), M_DEVBUF, M_NOWAIT | M_ZERO); if (ap == NULL) { printf("%s: unable to allocate memory for port %d\n", DEVNAME(sc), port); goto reterr; } #ifdef AHCI_DEBUG snprintf(ap->ap_name, sizeof(ap->ap_name), "%s.%d", DEVNAME(sc), port); #endif sc->sc_ports[port] = ap; if (bus_space_subregion(sc->sc_iot, sc->sc_ioh, AHCI_PORT_REGION(port), AHCI_PORT_SIZE, &ap->ap_ioh) != 0) { printf("%s: unable to create register window for port %d\n", DEVNAME(sc), port); goto freeport; } ap->ap_sc = sc; #ifdef AHCI_COALESCE ap->ap_num = port; #endif TAILQ_INIT(&ap->ap_ccb_free); TAILQ_INIT(&ap->ap_ccb_pending); mtx_init(&ap->ap_ccb_mtx, IPL_BIO); /* Disable port interrupts */ ahci_pwrite(ap, AHCI_PREG_IE, 0); /* Sec 10.1.2 - deinitialise port if it is already running */ cmd = ahci_pread(ap, AHCI_PREG_CMD); if (ISSET(cmd, (AHCI_PREG_CMD_ST | AHCI_PREG_CMD_CR | AHCI_PREG_CMD_FRE | AHCI_PREG_CMD_FR)) || ISSET(ahci_pread(ap, AHCI_PREG_SCTL), AHCI_PREG_SCTL_DET)) { int r; r = ahci_port_stop(ap, 1); if (r) { printf("%s: unable to disable %s, ignoring port %d\n", DEVNAME(sc), r == 2 ? "CR" : "FR", port); rc = ENXIO; goto freeport; } /* Write DET to zero */ ahci_pwrite(ap, AHCI_PREG_SCTL, 0); } /* Allocate RFIS */ ap->ap_dmamem_rfis = ahci_dmamem_alloc(sc, sizeof(struct ahci_rfis)); if (ap->ap_dmamem_rfis == NULL) goto nomem; /* Setup RFIS base address */ ap->ap_rfis = (struct ahci_rfis *) AHCI_DMA_KVA(ap->ap_dmamem_rfis); dva = AHCI_DMA_DVA(ap->ap_dmamem_rfis); ahci_pwrite(ap, AHCI_PREG_FBU, (u_int32_t)(dva >> 32)); ahci_pwrite(ap, AHCI_PREG_FB, (u_int32_t)dva); /* Enable FIS reception and activate port. */ cmd = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; cmd |= AHCI_PREG_CMD_FRE | AHCI_PREG_CMD_POD | AHCI_PREG_CMD_SUD; ahci_pwrite(ap, AHCI_PREG_CMD, cmd | AHCI_PREG_CMD_ICC_ACTIVE); /* Check whether port activated. Skip it if not. */ cmd = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; if (!ISSET(cmd, AHCI_PREG_CMD_FRE)) { rc = ENXIO; goto freeport; } /* Allocate a CCB for each command slot */ ap->ap_ccbs = malloc(sizeof(struct ahci_ccb) * sc->sc_ncmds, M_DEVBUF, M_NOWAIT | M_ZERO); if (ap->ap_ccbs == NULL) { printf("%s: unable to allocate command list for port %d\n", DEVNAME(sc), port); goto freeport; } /* Command List Structures and Command Tables */ ap->ap_dmamem_cmd_list = ahci_dmamem_alloc(sc, sc->sc_ncmds * sizeof(struct ahci_cmd_hdr)); ap->ap_dmamem_cmd_table = ahci_dmamem_alloc(sc, sc->sc_ncmds * sizeof(struct ahci_cmd_table)); if (ap->ap_dmamem_cmd_table == NULL || ap->ap_dmamem_cmd_list == NULL) { nomem: printf("%s: unable to allocate DMA memory for port %d\n", DEVNAME(sc), port); goto freeport; } /* Setup command list base address */ dva = AHCI_DMA_DVA(ap->ap_dmamem_cmd_list); ahci_pwrite(ap, AHCI_PREG_CLBU, (u_int32_t)(dva >> 32)); ahci_pwrite(ap, AHCI_PREG_CLB, (u_int32_t)dva); /* Split CCB allocation into CCBs and assign to command header/table */ hdr = AHCI_DMA_KVA(ap->ap_dmamem_cmd_list); table = AHCI_DMA_KVA(ap->ap_dmamem_cmd_table); for (i = 0; i < sc->sc_ncmds; i++) { ccb = &ap->ap_ccbs[i]; if (bus_dmamap_create(sc->sc_dmat, MAXPHYS, AHCI_MAX_PRDT, (4 * 1024 * 1024), 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &ccb->ccb_dmamap) != 0) { printf("%s: unable to create dmamap for port %d " "ccb %d\n", DEVNAME(sc), port, i); goto freeport; } ccb->ccb_slot = i; ccb->ccb_port = ap; ccb->ccb_cmd_hdr = &hdr[i]; ccb->ccb_cmd_table = &table[i]; dva = AHCI_DMA_DVA(ap->ap_dmamem_cmd_table) + ccb->ccb_slot * sizeof(struct ahci_cmd_table); ccb->ccb_cmd_hdr->ctba_hi = htole32((u_int32_t)(dva >> 32)); ccb->ccb_cmd_hdr->ctba_lo = htole32((u_int32_t)dva); ccb->ccb_xa.fis = (struct ata_fis_h2d *)ccb->ccb_cmd_table->cfis; ccb->ccb_xa.packetcmd = ccb->ccb_cmd_table->acmd; ccb->ccb_xa.tag = i; ccb->ccb_xa.ata_put_xfer = ahci_ata_put_xfer; ccb->ccb_xa.state = ATA_S_COMPLETE; ahci_put_ccb(ccb); } /* Wait for ICC change to complete */ ahci_pwait_clr(ap, AHCI_PREG_CMD, AHCI_PREG_CMD_ICC); /* Reset port */ rc = ahci_port_portreset(ap); switch (rc) { case ENODEV: switch (ahci_pread(ap, AHCI_PREG_SSTS) & AHCI_PREG_SSTS_DET) { case AHCI_PREG_SSTS_DET_DEV_NE: printf("%s: device not communicating on port %d\n", DEVNAME(sc), port); break; case AHCI_PREG_SSTS_DET_PHYOFFLINE: printf("%s: PHY offline on port %d\n", DEVNAME(sc), port); break; default: DPRINTF(AHCI_D_VERBOSE, "%s: no device detected " "on port %d\n", DEVNAME(sc), port); break; } goto freeport; case EBUSY: printf("%s: device on port %d didn't come ready, " "TFD: 0x%b\n", DEVNAME(sc), port, ahci_pread(ap, AHCI_PREG_TFD), AHCI_PFMT_TFD_STS); /* Try a soft reset to clear busy */ rc = ahci_port_softreset(ap); if (rc) { printf("%s: unable to communicate " "with device on port %d\n", DEVNAME(sc), port); goto freeport; } break; default: break; } DPRINTF(AHCI_D_VERBOSE, "%s: detected device on port %d\n", DEVNAME(sc), port); /* Enable command transfers on port */ if (ahci_port_start(ap, 0)) { printf("%s: failed to start command DMA on port %d, " "disabling\n", DEVNAME(sc), port); rc = ENXIO; /* couldn't start port */ } /* Flush interrupts for port */ ahci_pwrite(ap, AHCI_PREG_IS, ahci_pread(ap, AHCI_PREG_IS)); ahci_write(sc, AHCI_REG_IS, 1 << port); /* Enable port interrupts */ ahci_pwrite(ap, AHCI_PREG_IE, AHCI_PREG_IE_TFEE | AHCI_PREG_IE_HBFE | AHCI_PREG_IE_IFE | AHCI_PREG_IE_OFE | AHCI_PREG_IE_DPE | AHCI_PREG_IE_UFE | #ifdef AHCI_COALESCE ((sc->sc_ccc_ports & (1 << port)) ? 0 : (AHCI_PREG_IE_SDBE | AHCI_PREG_IE_DHRE)) #else AHCI_PREG_IE_SDBE | AHCI_PREG_IE_DHRE #endif ); freeport: if (rc != 0) ahci_port_free(sc, port); reterr: return (rc); } void ahci_port_free(struct ahci_softc *sc, u_int port) { struct ahci_port *ap = sc->sc_ports[port]; struct ahci_ccb *ccb; /* Ensure port is disabled and its interrupts are flushed */ if (ap->ap_sc) { ahci_pwrite(ap, AHCI_PREG_CMD, 0); ahci_pwrite(ap, AHCI_PREG_IE, 0); ahci_pwrite(ap, AHCI_PREG_IS, ahci_pread(ap, AHCI_PREG_IS)); ahci_write(sc, AHCI_REG_IS, 1 << port); } if (ap->ap_ccbs) { while ((ccb = ahci_get_ccb(ap)) != NULL) bus_dmamap_destroy(sc->sc_dmat, ccb->ccb_dmamap); free(ap->ap_ccbs, M_DEVBUF); } if (ap->ap_dmamem_cmd_list) ahci_dmamem_free(sc, ap->ap_dmamem_cmd_list); if (ap->ap_dmamem_rfis) ahci_dmamem_free(sc, ap->ap_dmamem_rfis); if (ap->ap_dmamem_cmd_table) ahci_dmamem_free(sc, ap->ap_dmamem_cmd_table); /* bus_space(9) says we dont free the subregions handle */ free(ap, M_DEVBUF); sc->sc_ports[port] = NULL; } int ahci_port_start(struct ahci_port *ap, int fre_only) { u_int32_t r; /* Turn on FRE (and ST) */ r = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; r |= AHCI_PREG_CMD_FRE; if (!fre_only) r |= AHCI_PREG_CMD_ST; ahci_pwrite(ap, AHCI_PREG_CMD, r); #ifdef AHCI_COALESCE /* (Re-)enable coalescing on the port. */ if (ap->ap_sc->sc_ccc_ports & (1 << ap->ap_num)) { ap->ap_sc->sc_ccc_ports_cur |= (1 << ap->ap_num); ahci_write(ap->ap_sc, AHCI_REG_CCC_PORTS, ap->ap_sc->sc_ccc_ports_cur); } #endif if (!(ap->ap_sc->sc_flags & AHCI_F_IGN_FR)) { /* Wait for FR to come on */ if (ahci_pwait_set(ap, AHCI_PREG_CMD, AHCI_PREG_CMD_FR)) return (2); } /* Wait for CR to come on */ if (!fre_only && ahci_pwait_set(ap, AHCI_PREG_CMD, AHCI_PREG_CMD_CR)) return (1); return (0); } int ahci_port_stop(struct ahci_port *ap, int stop_fis_rx) { u_int32_t r; #ifdef AHCI_COALESCE /* Disable coalescing on the port while it is stopped. */ if (ap->ap_sc->sc_ccc_ports & (1 << ap->ap_num)) { ap->ap_sc->sc_ccc_ports_cur &= ~(1 << ap->ap_num); ahci_write(ap->ap_sc, AHCI_REG_CCC_PORTS, ap->ap_sc->sc_ccc_ports_cur); } #endif /* Turn off ST (and FRE) */ r = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; r &= ~AHCI_PREG_CMD_ST; if (stop_fis_rx) r &= ~AHCI_PREG_CMD_FRE; ahci_pwrite(ap, AHCI_PREG_CMD, r); /* Wait for CR to go off */ if (ahci_pwait_clr(ap, AHCI_PREG_CMD, AHCI_PREG_CMD_CR)) return (1); /* Wait for FR to go off */ if (stop_fis_rx && ahci_pwait_clr(ap, AHCI_PREG_CMD, AHCI_PREG_CMD_FR)) return (2); return (0); } /* AHCI command list override -> forcibly clear TFD.STS.{BSY,DRQ} */ int ahci_port_clo(struct ahci_port *ap) { struct ahci_softc *sc = ap->ap_sc; u_int32_t cmd; /* Only attempt CLO if supported by controller */ if (!ISSET(ahci_read(sc, AHCI_REG_CAP), AHCI_REG_CAP_SCLO)) return (1); /* Issue CLO */ cmd = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; #ifdef DIAGNOSTIC if (ISSET(cmd, AHCI_PREG_CMD_ST)) printf("%s: CLO requested while port running\n", PORTNAME(ap)); #endif ahci_pwrite(ap, AHCI_PREG_CMD, cmd | AHCI_PREG_CMD_CLO); /* Wait for completion */ if (ahci_pwait_clr(ap, AHCI_PREG_CMD, AHCI_PREG_CMD_CLO)) { printf("%s: CLO did not complete\n", PORTNAME(ap)); return (1); } return (0); } /* AHCI soft reset, Section 10.4.1 */ int ahci_port_softreset(struct ahci_port *ap) { struct ahci_ccb *ccb = NULL; struct ahci_cmd_hdr *cmd_slot; u_int8_t *fis; int s, rc = EIO; u_int32_t cmd; DPRINTF(AHCI_D_VERBOSE, "%s: soft reset\n", PORTNAME(ap)); s = splbio(); /* Save previous command register state */ cmd = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; /* Idle port */ if (ahci_port_stop(ap, 0)) { printf("%s: failed to stop port, cannot softreset\n", PORTNAME(ap)); goto err; } /* Request CLO if device appears hung */ if (ISSET(ahci_pread(ap, AHCI_PREG_TFD), AHCI_PREG_TFD_STS_BSY | AHCI_PREG_TFD_STS_DRQ)) ahci_port_clo(ap); /* Clear port errors to permit TFD transfer */ ahci_pwrite(ap, AHCI_PREG_SERR, ahci_pread(ap, AHCI_PREG_SERR)); /* Restart port */ if (ahci_port_start(ap, 0)) { printf("%s: failed to start port, cannot softreset\n", PORTNAME(ap)); goto err; } /* Check whether CLO worked */ if (ahci_pwait_clr(ap, AHCI_PREG_TFD, AHCI_PREG_TFD_STS_BSY | AHCI_PREG_TFD_STS_DRQ)) { printf("%s: CLO %s, need port reset\n", PORTNAME(ap), ISSET(ahci_read(ap->ap_sc, AHCI_REG_CAP), AHCI_REG_CAP_SCLO) ? "failed" : "unsupported"); rc = EBUSY; goto err; } /* Prep first D2H command with SRST feature & clear busy/reset flags */ ccb = ahci_get_err_ccb(ap); cmd_slot = ccb->ccb_cmd_hdr; bzero(ccb->ccb_cmd_table, sizeof(struct ahci_cmd_table)); fis = ccb->ccb_cmd_table->cfis; fis[0] = 0x27; /* Host to device */ fis[15] = 0x04; /* SRST DEVCTL */ cmd_slot->prdtl = 0; cmd_slot->flags = htole16(5); /* FIS length: 5 DWORDS */ cmd_slot->flags |= htole16(AHCI_CMD_LIST_FLAG_C); /* Clear busy on OK */ cmd_slot->flags |= htole16(AHCI_CMD_LIST_FLAG_R); /* Reset */ cmd_slot->flags |= htole16(AHCI_CMD_LIST_FLAG_W); /* Write */ ccb->ccb_xa.state = ATA_S_PENDING; if (ahci_poll(ccb, 1000, NULL) != 0) goto err; /* Prep second D2H command to read status and complete reset sequence */ fis[0] = 0x27; /* Host to device */ fis[15] = 0; cmd_slot->prdtl = 0; cmd_slot->flags = htole16(5); /* FIS length: 5 DWORDS */ cmd_slot->flags |= htole16(AHCI_CMD_LIST_FLAG_W); ccb->ccb_xa.state = ATA_S_PENDING; if (ahci_poll(ccb, 1000, NULL) != 0) goto err; if (ahci_pwait_clr(ap, AHCI_PREG_TFD, AHCI_PREG_TFD_STS_BSY | AHCI_PREG_TFD_STS_DRQ | AHCI_PREG_TFD_STS_ERR)) { printf("%s: device didn't come ready after reset, TFD: 0x%b\n", PORTNAME(ap), ahci_pread(ap, AHCI_PREG_TFD), AHCI_PFMT_TFD_STS); rc = EBUSY; goto err; } rc = 0; err: if (ccb != NULL) { /* Abort our command, if it failed, by stopping command DMA. */ if (rc != 0 && ISSET(ap->ap_active, 1 << ccb->ccb_slot)) { printf("%s: stopping the port, softreset slot %d was " "still active.\n", PORTNAME(ap), ccb->ccb_slot); ahci_port_stop(ap, 0); } ccb->ccb_xa.state = ATA_S_ERROR; ahci_put_err_ccb(ccb); } /* Restore saved CMD register state */ ahci_pwrite(ap, AHCI_PREG_CMD, cmd); splx(s); return (rc); } /* AHCI port reset, Section 10.4.2 */ int ahci_port_portreset(struct ahci_port *ap) { u_int32_t cmd, r; int rc; DPRINTF(AHCI_D_VERBOSE, "%s: port reset\n", PORTNAME(ap)); /* Save previous command register state */ cmd = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; /* Clear ST, ignoring failure */ ahci_port_stop(ap, 0); /* Perform device detection */ ahci_pwrite(ap, AHCI_PREG_SCTL, 0); delay(10000); r = AHCI_PREG_SCTL_IPM_DISABLED | AHCI_PREG_SCTL_DET_INIT; if ((ap->ap_sc->sc_dev.dv_cfdata->cf_flags & 0x01) != 0) { DPRINTF(AHCI_D_VERBOSE, "%s: forcing GEN1\n", PORTNAME(ap)); r |= AHCI_PREG_SCTL_SPD_GEN1; } else r |= AHCI_PREG_SCTL_SPD_ANY; ahci_pwrite(ap, AHCI_PREG_SCTL, r); delay(10000); /* wait at least 1ms for COMRESET to be sent */ r &= ~AHCI_PREG_SCTL_DET_INIT; r |= AHCI_PREG_SCTL_DET_NONE; ahci_pwrite(ap, AHCI_PREG_SCTL, r); delay(10000); /* Wait for device to be detected and communications established */ if (ahci_pwait_eq(ap, AHCI_PREG_SSTS, AHCI_PREG_SSTS_DET, AHCI_PREG_SSTS_DET_DEV)) { rc = ENODEV; goto err; } /* Clear SERR (incl X bit), so TFD can update */ ahci_pwrite(ap, AHCI_PREG_SERR, ahci_pread(ap, AHCI_PREG_SERR)); /* Wait for device to become ready */ /* XXX maybe more than the default wait is appropriate here? */ if (ahci_pwait_clr(ap, AHCI_PREG_TFD, AHCI_PREG_TFD_STS_BSY | AHCI_PREG_TFD_STS_DRQ | AHCI_PREG_TFD_STS_ERR)) { rc = EBUSY; goto err; } rc = 0; err: /* Restore preserved port state */ ahci_pwrite(ap, AHCI_PREG_CMD, cmd); return (rc); } int ahci_load_prdt(struct ahci_ccb *ccb) { struct ahci_port *ap = ccb->ccb_port; struct ahci_softc *sc = ap->ap_sc; struct ata_xfer *xa = &ccb->ccb_xa; struct ahci_prdt *prdt = ccb->ccb_cmd_table->prdt, *prd; bus_dmamap_t dmap = ccb->ccb_dmamap; struct ahci_cmd_hdr *cmd_slot = ccb->ccb_cmd_hdr; u_int64_t addr; int i, error; if (xa->datalen == 0) { ccb->ccb_cmd_hdr->prdtl = 0; return (0); } error = bus_dmamap_load(sc->sc_dmat, dmap, xa->data, xa->datalen, NULL, (xa->flags & ATA_F_NOWAIT) ? BUS_DMA_NOWAIT : BUS_DMA_WAITOK); if (error != 0) { printf("%s: error %d loading dmamap\n", PORTNAME(ap), error); return (1); } for (i = 0; i < dmap->dm_nsegs; i++) { prd = &prdt[i]; addr = dmap->dm_segs[i].ds_addr; prd->dba_hi = htole32((u_int32_t)(addr >> 32)); prd->dba_lo = htole32((u_int32_t)addr); #ifdef DIAGNOSTIC if (addr & 1) { printf("%s: requested DMA at an odd address %llx\n", PORTNAME(ap), (unsigned long long)addr); goto diagerr; } if (dmap->dm_segs[i].ds_len & 1) { printf("%s: requested DMA length %d is not even\n", PORTNAME(ap), (int)dmap->dm_segs[i].ds_len); goto diagerr; } #endif prd->flags = htole32(dmap->dm_segs[i].ds_len - 1); } if (xa->flags & ATA_F_PIO) prd->flags |= htole32(AHCI_PRDT_FLAG_INTR); cmd_slot->prdtl = htole16(dmap->dm_nsegs); bus_dmamap_sync(sc->sc_dmat, dmap, 0, dmap->dm_mapsize, (xa->flags & ATA_F_READ) ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE); return (0); #ifdef DIAGNOSTIC diagerr: bus_dmamap_unload(sc->sc_dmat, dmap); return (1); #endif } void ahci_unload_prdt(struct ahci_ccb *ccb) { struct ahci_port *ap = ccb->ccb_port; struct ahci_softc *sc = ap->ap_sc; struct ata_xfer *xa = &ccb->ccb_xa; bus_dmamap_t dmap = ccb->ccb_dmamap; if (xa->datalen != 0) { bus_dmamap_sync(sc->sc_dmat, dmap, 0, dmap->dm_mapsize, (xa->flags & ATA_F_READ) ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, dmap); if (ccb->ccb_xa.flags & ATA_F_NCQ) xa->resid = 0; else xa->resid = xa->datalen - letoh32(ccb->ccb_cmd_hdr->prdbc); } } int ahci_poll(struct ahci_ccb *ccb, int timeout, void (*timeout_fn)(void *)) { struct ahci_port *ap = ccb->ccb_port; int s; s = splbio(); ahci_start(ccb); do { if (ISSET(ahci_port_intr(ap, AHCI_PREG_CI_ALL_SLOTS), 1 << ccb->ccb_slot)) { splx(s); return (0); } delay(1000); } while (--timeout > 0); /* Run timeout while at splbio, otherwise ahci_intr could interfere. */ if (timeout_fn != NULL) timeout_fn(ccb); splx(s); return (1); } void ahci_start(struct ahci_ccb *ccb) { struct ahci_port *ap = ccb->ccb_port; struct ahci_softc *sc = ap->ap_sc; KASSERT(ccb->ccb_xa.state == ATA_S_PENDING); /* Zero transferred byte count before transfer */ ccb->ccb_cmd_hdr->prdbc = 0; /* Sync command list entry and corresponding command table entry */ bus_dmamap_sync(sc->sc_dmat, AHCI_DMA_MAP(ap->ap_dmamem_cmd_list), ccb->ccb_slot * sizeof(struct ahci_cmd_hdr), sizeof(struct ahci_cmd_hdr), BUS_DMASYNC_PREWRITE); bus_dmamap_sync(sc->sc_dmat, AHCI_DMA_MAP(ap->ap_dmamem_cmd_table), ccb->ccb_slot * sizeof(struct ahci_cmd_table), sizeof(struct ahci_cmd_table), BUS_DMASYNC_PREWRITE); /* Prepare RFIS area for write by controller */ bus_dmamap_sync(sc->sc_dmat, AHCI_DMA_MAP(ap->ap_dmamem_rfis), 0, sizeof(struct ahci_rfis), BUS_DMASYNC_PREREAD); if (ccb->ccb_xa.flags & ATA_F_NCQ) { /* Issue NCQ commands only when there are no outstanding * standard commands. */ if (ap->ap_active != 0 || !TAILQ_EMPTY(&ap->ap_ccb_pending)) TAILQ_INSERT_TAIL(&ap->ap_ccb_pending, ccb, ccb_entry); else { KASSERT(ap->ap_active_cnt == 0); ap->ap_sactive |= (1 << ccb->ccb_slot); ccb->ccb_xa.state = ATA_S_ONCHIP; ahci_pwrite(ap, AHCI_PREG_SACT, 1 << ccb->ccb_slot); ahci_pwrite(ap, AHCI_PREG_CI, 1 << ccb->ccb_slot); } } else { /* Wait for all NCQ commands to finish before issuing standard * command. */ if (ap->ap_sactive != 0 || ap->ap_active_cnt == 2) TAILQ_INSERT_TAIL(&ap->ap_ccb_pending, ccb, ccb_entry); else if (ap->ap_active_cnt < 2) { ap->ap_active |= 1 << ccb->ccb_slot; ccb->ccb_xa.state = ATA_S_ONCHIP; ahci_pwrite(ap, AHCI_PREG_CI, 1 << ccb->ccb_slot); ap->ap_active_cnt++; } } } void ahci_issue_pending_ncq_commands(struct ahci_port *ap) { struct ahci_ccb *nextccb; u_int32_t sact_change = 0; KASSERT(ap->ap_active_cnt == 0); nextccb = TAILQ_FIRST(&ap->ap_ccb_pending); if (nextccb == NULL || !(nextccb->ccb_xa.flags & ATA_F_NCQ)) return; /* Start all the NCQ commands at the head of the pending list. */ do { TAILQ_REMOVE(&ap->ap_ccb_pending, nextccb, ccb_entry); sact_change |= 1 << nextccb->ccb_slot; nextccb->ccb_xa.state = ATA_S_ONCHIP; nextccb = TAILQ_FIRST(&ap->ap_ccb_pending); } while (nextccb && (nextccb->ccb_xa.flags & ATA_F_NCQ)); ap->ap_sactive |= sact_change; ahci_pwrite(ap, AHCI_PREG_SACT, sact_change); ahci_pwrite(ap, AHCI_PREG_CI, sact_change); return; } void ahci_issue_pending_commands(struct ahci_port *ap, int last_was_ncq) { struct ahci_ccb *nextccb; nextccb = TAILQ_FIRST(&ap->ap_ccb_pending); if (nextccb && (nextccb->ccb_xa.flags & ATA_F_NCQ)) { KASSERT(last_was_ncq == 0); /* otherwise it should have * been started already. */ /* Issue NCQ commands only when there are no outstanding * standard commands. */ ap->ap_active_cnt--; if (ap->ap_active == 0) ahci_issue_pending_ncq_commands(ap); else KASSERT(ap->ap_active_cnt == 1); } else if (nextccb) { if (ap->ap_sactive != 0 || last_was_ncq) KASSERT(ap->ap_active_cnt == 0); /* Wait for all NCQ commands to finish before issuing standard * command. */ if (ap->ap_sactive != 0) return; /* Keep up to 2 standard commands on-chip at a time. */ do { TAILQ_REMOVE(&ap->ap_ccb_pending, nextccb, ccb_entry); ap->ap_active |= 1 << nextccb->ccb_slot; nextccb->ccb_xa.state = ATA_S_ONCHIP; ahci_pwrite(ap, AHCI_PREG_CI, 1 << nextccb->ccb_slot); if (last_was_ncq) ap->ap_active_cnt++; if (ap->ap_active_cnt == 2) break; KASSERT(ap->ap_active_cnt == 1); nextccb = TAILQ_FIRST(&ap->ap_ccb_pending); } while (nextccb && !(nextccb->ccb_xa.flags & ATA_F_NCQ)); } else if (!last_was_ncq) { KASSERT(ap->ap_active_cnt == 1 || ap->ap_active_cnt == 2); /* Standard command finished, none waiting to start. */ ap->ap_active_cnt--; } else { KASSERT(ap->ap_active_cnt == 0); /* NCQ command finished. */ } } int ahci_intr(void *arg) { struct ahci_softc *sc = arg; u_int32_t is, ack = 0; int port; /* Read global interrupt status */ is = ahci_read(sc, AHCI_REG_IS); if (is == 0 || is == 0xffffffff) return (0); ack = is; #ifdef AHCI_COALESCE /* Check coalescing interrupt first */ if (is & sc->sc_ccc_mask) { DPRINTF(AHCI_D_INTR, "%s: command coalescing interrupt\n", DEVNAME(sc)); is &= ~sc->sc_ccc_mask; is |= sc->sc_ccc_ports_cur; } #endif /* Process interrupts for each port */ while (is) { port = ffs(is) - 1; if (sc->sc_ports[port]) ahci_port_intr(sc->sc_ports[port], AHCI_PREG_CI_ALL_SLOTS); is &= ~(1 << port); } /* Finally, acknowledge global interrupt */ ahci_write(sc, AHCI_REG_IS, ack); return (1); } u_int32_t ahci_port_intr(struct ahci_port *ap, u_int32_t ci_mask) { struct ahci_softc *sc = ap->ap_sc; u_int32_t is, ci_saved, ci_masked, processed = 0; int slot, need_restart = 0; struct ahci_ccb *ccb; volatile u_int32_t *active; #ifdef DIAGNOSTIC u_int32_t tmp; #endif is = ahci_pread(ap, AHCI_PREG_IS); /* Ack port interrupt only if checking all command slots. */ if (ci_mask == AHCI_PREG_CI_ALL_SLOTS) ahci_pwrite(ap, AHCI_PREG_IS, is); if (is) DPRINTF(AHCI_D_INTR, "%s: interrupt: %b\n", PORTNAME(ap), is, AHCI_PFMT_IS); if (ap->ap_sactive) { /* Active NCQ commands - use SActive instead of CI */ KASSERT(ap->ap_active == 0); KASSERT(ap->ap_active_cnt == 0); ci_saved = ahci_pread(ap, AHCI_PREG_SACT); active = &ap->ap_sactive; } else { /* Save CI */ ci_saved = ahci_pread(ap, AHCI_PREG_CI); active = &ap->ap_active; } /* Command failed. See AHCI 1.1 spec 6.2.2.1 and 6.2.2.2. */ if (is & AHCI_PREG_IS_TFES) { u_int32_t tfd, serr; int err_slot; tfd = ahci_pread(ap, AHCI_PREG_TFD); serr = ahci_pread(ap, AHCI_PREG_SERR); if (ap->ap_sactive == 0) { /* Errored slot is easy to determine from CMD. */ err_slot = AHCI_PREG_CMD_CCS(ahci_pread(ap, AHCI_PREG_CMD)); ccb = &ap->ap_ccbs[err_slot]; /* Preserve received taskfile data from the RFIS. */ memcpy(&ccb->ccb_xa.rfis, ap->ap_rfis->rfis, sizeof(struct ata_fis_d2h)); } else err_slot = -1; /* Must extract error from log page */ DPRINTF(AHCI_D_VERBOSE, "%s: errored slot %d, TFD: %b, SERR:" " %b, DIAG: %b\n", PORTNAME(ap), err_slot, tfd, AHCI_PFMT_TFD_STS, AHCI_PREG_SERR_ERR(serr), AHCI_PFMT_SERR_ERR, AHCI_PREG_SERR_DIAG(serr), AHCI_PFMT_SERR_DIAG); /* Turn off ST to clear CI and SACT. */ ahci_port_stop(ap, 0); need_restart = 1; /* Clear SERR to enable capturing new errors. */ ahci_pwrite(ap, AHCI_PREG_SERR, serr); /* Acknowledge the interrupts we can recover from. */ ahci_pwrite(ap, AHCI_PREG_IS, AHCI_PREG_IS_TFES | AHCI_PREG_IS_IFS); is = ahci_pread(ap, AHCI_PREG_IS); /* If device hasn't cleared its busy status, try to idle it. */ if (ISSET(tfd, AHCI_PREG_TFD_STS_BSY | AHCI_PREG_TFD_STS_DRQ)) { printf("%s: attempting to idle device\n", PORTNAME(ap)); if (ahci_port_softreset(ap)) { printf("%s: failed to soft reset device\n", PORTNAME(ap)); if (ahci_port_portreset(ap)) { printf("%s: failed to port reset " "device, give up on it\n", PORTNAME(ap)); goto fatal; } } /* Had to reset device, can't gather extended info. */ } else if (ap->ap_sactive) { /* Recover the NCQ error from log page 10h. */ ahci_port_read_ncq_error(ap, &err_slot); if (err_slot < 0) goto failall; DPRINTF(AHCI_D_VERBOSE, "%s: NCQ errored slot %d\n", PORTNAME(ap), err_slot); ccb = &ap->ap_ccbs[err_slot]; } else { /* Didn't reset, could gather extended info from log. */ } /* * If we couldn't determine the errored slot, reset the port * and fail all the active slots. */ if (err_slot == -1) { if (ahci_port_softreset(ap) != 0 && ahci_port_portreset(ap) != 0) { printf("%s: couldn't reset after NCQ error, " "disabling device.\n", PORTNAME(ap)); goto fatal; } printf("%s: couldn't recover NCQ error, failing " "all outstanding commands.\n", PORTNAME(ap)); goto failall; } /* Clear the failed command in saved CI so completion runs. */ ci_saved &= ~(1 << err_slot); /* Note the error in the ata_xfer. */ KASSERT(ccb->ccb_xa.state == ATA_S_ONCHIP); ccb->ccb_xa.state = ATA_S_ERROR; #ifdef DIAGNOSTIC /* There may only be one outstanding standard command now. */ if (ap->ap_sactive == 0) { tmp = ci_saved; if (tmp) { slot = ffs(tmp) - 1; tmp &= ~(1 << slot); KASSERT(tmp == 0); } } #endif } /* Check for remaining errors - they are fatal. */ if (is & (AHCI_PREG_IS_TFES | AHCI_PREG_IS_HBFS | AHCI_PREG_IS_IFS | AHCI_PREG_IS_OFS | AHCI_PREG_IS_UFS)) { printf("%s: unrecoverable errors (IS: %b), disabling port.\n", PORTNAME(ap), is, AHCI_PFMT_IS); /* XXX try recovery first */ goto fatal; } /* Fail all outstanding commands if we know the port won't recover. */ if (ap->ap_state == AP_S_FATAL_ERROR) { fatal: ap->ap_state = AP_S_FATAL_ERROR; failall: /* Ensure port is shut down. */ ahci_port_stop(ap, 1); /* Error all the active slots. */ ci_masked = ci_saved & *active; while (ci_masked) { slot = ffs(ci_masked) - 1; ccb = &ap->ap_ccbs[slot]; ci_masked &= ~(1 << slot); ccb->ccb_xa.state = ATA_S_ERROR; } /* Run completion for all active slots. */ ci_saved &= ~*active; /* Don't restart the port if our problems were deemed fatal. */ if (ap->ap_state == AP_S_FATAL_ERROR) need_restart = 0; } /* * CCB completion is detected by noticing its slot's bit in CI has * changed to zero some time after we activated it. * If we are polling, we may only be interested in particular slot(s). */ ci_masked = ~ci_saved & *active & ci_mask; while (ci_masked) { slot = ffs(ci_masked) - 1; ccb = &ap->ap_ccbs[slot]; ci_masked &= ~(1 << slot); DPRINTF(AHCI_D_INTR, "%s: slot %d is complete%s\n", PORTNAME(ap), slot, ccb->ccb_xa.state == ATA_S_ERROR ? " (error)" : ""); bus_dmamap_sync(sc->sc_dmat, AHCI_DMA_MAP(ap->ap_dmamem_cmd_list), ccb->ccb_slot * sizeof(struct ahci_cmd_hdr), sizeof(struct ahci_cmd_hdr), BUS_DMASYNC_POSTWRITE); bus_dmamap_sync(sc->sc_dmat, AHCI_DMA_MAP(ap->ap_dmamem_cmd_table), ccb->ccb_slot * sizeof(struct ahci_cmd_table), sizeof(struct ahci_cmd_table), BUS_DMASYNC_POSTWRITE); bus_dmamap_sync(sc->sc_dmat, AHCI_DMA_MAP(ap->ap_dmamem_rfis), 0, sizeof(struct ahci_rfis), BUS_DMASYNC_POSTREAD); *active &= ~(1 << ccb->ccb_slot); ccb->ccb_done(ccb); processed |= 1 << ccb->ccb_slot; } if (need_restart) { /* Restart command DMA on the port */ ahci_port_start(ap, 0); /* Re-enable outstanding commands on port. */ if (ci_saved) { #ifdef DIAGNOSTIC tmp = ci_saved; while (tmp) { slot = ffs(tmp) - 1; tmp &= ~(1 << slot); ccb = &ap->ap_ccbs[slot]; KASSERT(ccb->ccb_xa.state == ATA_S_ONCHIP); KASSERT((!!(ccb->ccb_xa.flags & ATA_F_NCQ)) == (!!ap->ap_sactive)); } #endif DPRINTF(AHCI_D_VERBOSE, "%s: ahci_port_intr " "re-enabling%s slots %08x\n", PORTNAME(ap), ap->ap_sactive ? " NCQ" : "", ci_saved); if (ap->ap_sactive) ahci_pwrite(ap, AHCI_PREG_SACT, ci_saved); ahci_pwrite(ap, AHCI_PREG_CI, ci_saved); } } return (processed); } struct ahci_ccb * ahci_get_ccb(struct ahci_port *ap) { struct ahci_ccb *ccb; mtx_enter(&ap->ap_ccb_mtx); ccb = TAILQ_FIRST(&ap->ap_ccb_free); if (ccb != NULL) { KASSERT(ccb->ccb_xa.state == ATA_S_PUT); TAILQ_REMOVE(&ap->ap_ccb_free, ccb, ccb_entry); ccb->ccb_xa.state = ATA_S_SETUP; } mtx_leave(&ap->ap_ccb_mtx); return (ccb); } void ahci_put_ccb(struct ahci_ccb *ccb) { struct ahci_port *ap = ccb->ccb_port; #ifdef DIAGNOSTIC if (ccb->ccb_xa.state != ATA_S_COMPLETE && ccb->ccb_xa.state != ATA_S_TIMEOUT && ccb->ccb_xa.state != ATA_S_ERROR) { printf("%s: invalid ata_xfer state %02x in ahci_put_ccb, " "slot %d\n", PORTNAME(ccb->ccb_port), ccb->ccb_xa.state, ccb->ccb_slot); } #endif ccb->ccb_xa.state = ATA_S_PUT; mtx_enter(&ap->ap_ccb_mtx); TAILQ_INSERT_TAIL(&ap->ap_ccb_free, ccb, ccb_entry); mtx_leave(&ap->ap_ccb_mtx); } struct ahci_ccb * ahci_get_err_ccb(struct ahci_port *ap) { struct ahci_ccb *err_ccb; u_int32_t sact; splassert(IPL_BIO); /* No commands may be active on the chip. */ sact = ahci_pread(ap, AHCI_PREG_SACT); if (sact != 0) printf("ahci_get_err_ccb but SACT %08x != 0?\n", sact); KASSERT(ahci_pread(ap, AHCI_PREG_CI) == 0); #ifdef DIAGNOSTIC KASSERT(ap->ap_err_busy == 0); ap->ap_err_busy = 1; #endif /* Save outstanding command state. */ ap->ap_err_saved_active = ap->ap_active; ap->ap_err_saved_active_cnt = ap->ap_active_cnt; ap->ap_err_saved_sactive = ap->ap_sactive; /* * Pretend we have no commands outstanding, so that completions won't * run prematurely. */ ap->ap_active = ap->ap_active_cnt = ap->ap_sactive = 0; /* * Grab a CCB to use for error recovery. This should never fail, as * we ask atascsi to reserve one for us at init time. */ err_ccb = ahci_get_ccb(ap); KASSERT(err_ccb != NULL); err_ccb->ccb_xa.flags = 0; err_ccb->ccb_done = ahci_empty_done; return err_ccb; } void ahci_put_err_ccb(struct ahci_ccb *ccb) { struct ahci_port *ap = ccb->ccb_port; u_int32_t sact; splassert(IPL_BIO); #ifdef DIAGNOSTIC KASSERT(ap->ap_err_busy); #endif /* No commands may be active on the chip */ sact = ahci_pread(ap, AHCI_PREG_SACT); if (sact != 0) printf("ahci_port_err_ccb_restore but SACT %08x != 0?\n", sact); KASSERT(ahci_pread(ap, AHCI_PREG_CI) == 0); /* Done with the CCB */ ahci_put_ccb(ccb); /* Restore outstanding command state */ ap->ap_sactive = ap->ap_err_saved_sactive; ap->ap_active_cnt = ap->ap_err_saved_active_cnt; ap->ap_active = ap->ap_err_saved_active; #ifdef DIAGNOSTIC ap->ap_err_busy = 0; #endif } int ahci_port_read_ncq_error(struct ahci_port *ap, int *err_slotp) { struct ahci_ccb *ccb; struct ahci_cmd_hdr *cmd_slot; u_int32_t cmd; struct ata_fis_h2d *fis; int rc = EIO; DPRINTF(AHCI_D_VERBOSE, "%s: read log page\n", PORTNAME(ap)); /* Save command register state. */ cmd = ahci_pread(ap, AHCI_PREG_CMD) & ~AHCI_PREG_CMD_ICC; /* Port should have been idled already. Start it. */ KASSERT((cmd & AHCI_PREG_CMD_CR) == 0); ahci_port_start(ap, 0); /* Prep error CCB for READ LOG EXT, page 10h, 1 sector. */ ccb = ahci_get_err_ccb(ap); ccb->ccb_xa.flags = ATA_F_NOWAIT | ATA_F_READ | ATA_F_POLL; ccb->ccb_xa.data = ap->ap_err_scratch; ccb->ccb_xa.datalen = 512; cmd_slot = ccb->ccb_cmd_hdr; bzero(ccb->ccb_cmd_table, sizeof(struct ahci_cmd_table)); fis = (struct ata_fis_h2d *)ccb->ccb_cmd_table->cfis; fis->type = ATA_FIS_TYPE_H2D; fis->flags = ATA_H2D_FLAGS_CMD; fis->command = ATA_C_READ_LOG_EXT; fis->lba_low = 0x10; /* queued error log page (10h) */ fis->sector_count = 1; /* number of sectors (1) */ fis->sector_count_exp = 0; fis->lba_mid = 0; /* starting offset */ fis->lba_mid_exp = 0; fis->device = 0; cmd_slot->flags = htole16(5); /* FIS length: 5 DWORDS */ if (ahci_load_prdt(ccb) != 0) { rc = ENOMEM; /* XXX caller must abort all commands */ goto err; } ccb->ccb_xa.state = ATA_S_PENDING; if (ahci_poll(ccb, 1000, NULL) != 0) goto err; rc = 0; err: /* Abort our command, if it failed, by stopping command DMA. */ if (rc != 0 && ISSET(ap->ap_active, 1 << ccb->ccb_slot)) { printf("%s: log page read failed, slot %d was still active.\n", PORTNAME(ap), ccb->ccb_slot); ahci_port_stop(ap, 0); } /* Done with the error CCB now. */ ahci_unload_prdt(ccb); ahci_put_err_ccb(ccb); /* Extract failed register set and tags from the scratch space. */ if (rc == 0) { struct ata_log_page_10h *log; int err_slot; log = (struct ata_log_page_10h *)ap->ap_err_scratch; if (ISSET(log->err_regs.type, ATA_LOG_10H_TYPE_NOTQUEUED)) { /* Not queued bit was set - wasn't an NCQ error? */ printf("%s: read NCQ error page, but not an NCQ " "error?\n", PORTNAME(ap)); rc = ESRCH; } else { /* Copy back the log record as a D2H register FIS. */ *err_slotp = err_slot = log->err_regs.type & ATA_LOG_10H_TYPE_TAG_MASK; ccb = &ap->ap_ccbs[err_slot]; memcpy(&ccb->ccb_xa.rfis, &log->err_regs, sizeof(struct ata_fis_d2h)); ccb->ccb_xa.rfis.type = ATA_FIS_TYPE_D2H; ccb->ccb_xa.rfis.flags = 0; } } /* Restore saved CMD register state */ ahci_pwrite(ap, AHCI_PREG_CMD, cmd); return (rc); } struct ahci_dmamem * ahci_dmamem_alloc(struct ahci_softc *sc, size_t size) { struct ahci_dmamem *adm; int nsegs; adm = malloc(sizeof(*adm), M_DEVBUF, M_NOWAIT | M_ZERO); if (adm == NULL) return (NULL); adm->adm_size = size; if (bus_dmamap_create(sc->sc_dmat, size, 1, size, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &adm->adm_map) != 0) goto admfree; if (bus_dmamem_alloc(sc->sc_dmat, size, PAGE_SIZE, 0, &adm->adm_seg, 1, &nsegs, BUS_DMA_NOWAIT) != 0) goto destroy; if (bus_dmamem_map(sc->sc_dmat, &adm->adm_seg, nsegs, size, &adm->adm_kva, BUS_DMA_NOWAIT) != 0) goto free; if (bus_dmamap_load(sc->sc_dmat, adm->adm_map, adm->adm_kva, size, NULL, BUS_DMA_NOWAIT) != 0) goto unmap; bzero(adm->adm_kva, size); return (adm); unmap: bus_dmamem_unmap(sc->sc_dmat, adm->adm_kva, size); free: bus_dmamem_free(sc->sc_dmat, &adm->adm_seg, 1); destroy: bus_dmamap_destroy(sc->sc_dmat, adm->adm_map); admfree: free(adm, M_DEVBUF); return (NULL); } void ahci_dmamem_free(struct ahci_softc *sc, struct ahci_dmamem *adm) { bus_dmamap_unload(sc->sc_dmat, adm->adm_map); bus_dmamem_unmap(sc->sc_dmat, adm->adm_kva, adm->adm_size); bus_dmamem_free(sc->sc_dmat, &adm->adm_seg, 1); bus_dmamap_destroy(sc->sc_dmat, adm->adm_map); free(adm, M_DEVBUF); } u_int32_t ahci_read(struct ahci_softc *sc, bus_size_t r) { bus_space_barrier(sc->sc_iot, sc->sc_ioh, r, 4, BUS_SPACE_BARRIER_READ); return (bus_space_read_4(sc->sc_iot, sc->sc_ioh, r)); } void ahci_write(struct ahci_softc *sc, bus_size_t r, u_int32_t v) { bus_space_write_4(sc->sc_iot, sc->sc_ioh, r, v); bus_space_barrier(sc->sc_iot, sc->sc_ioh, r, 4, BUS_SPACE_BARRIER_WRITE); } int ahci_wait_ne(struct ahci_softc *sc, bus_size_t r, u_int32_t mask, u_int32_t target) { int i; for (i = 0; i < 1000; i++) { if ((ahci_read(sc, r) & mask) != target) return (0); delay(1000); } return (1); } u_int32_t ahci_pread(struct ahci_port *ap, bus_size_t r) { bus_space_barrier(ap->ap_sc->sc_iot, ap->ap_ioh, r, 4, BUS_SPACE_BARRIER_READ); return (bus_space_read_4(ap->ap_sc->sc_iot, ap->ap_ioh, r)); } void ahci_pwrite(struct ahci_port *ap, bus_size_t r, u_int32_t v) { bus_space_write_4(ap->ap_sc->sc_iot, ap->ap_ioh, r, v); bus_space_barrier(ap->ap_sc->sc_iot, ap->ap_ioh, r, 4, BUS_SPACE_BARRIER_WRITE); } int ahci_pwait_eq(struct ahci_port *ap, bus_size_t r, u_int32_t mask, u_int32_t target) { int i; for (i = 0; i < 1000; i++) { if ((ahci_pread(ap, r) & mask) == target) return (0); delay(1000); } return (1); } int ahci_ata_probe(void *xsc, int port) { struct ahci_softc *sc = xsc; struct ahci_port *ap = sc->sc_ports[port]; u_int32_t sig; if (ap == NULL) return (ATA_PORT_T_NONE); sig = ahci_pread(ap, AHCI_PREG_SIG); if ((sig & 0xffff0000) == (SATA_SIGNATURE_ATAPI & 0xffff0000)) return (ATA_PORT_T_ATAPI); else return (ATA_PORT_T_DISK); } void ahci_ata_free(void *xsc, int port) { } struct ata_xfer * ahci_ata_get_xfer(void *aaa_cookie, int port) { struct ahci_softc *sc = aaa_cookie; struct ahci_port *ap = sc->sc_ports[port]; struct ahci_ccb *ccb; ccb = ahci_get_ccb(ap); if (ccb == NULL) { DPRINTF(AHCI_D_XFER, "%s: ahci_ata_get_xfer: NULL ccb\n", PORTNAME(ap)); return (NULL); } DPRINTF(AHCI_D_XFER, "%s: ahci_ata_get_xfer got slot %d\n", PORTNAME(ap), ccb->ccb_slot); return ((struct ata_xfer *)ccb); } void ahci_ata_put_xfer(struct ata_xfer *xa) { struct ahci_ccb *ccb = (struct ahci_ccb *)xa; DPRINTF(AHCI_D_XFER, "ahci_ata_put_xfer slot %d\n", ccb->ccb_slot); ahci_put_ccb(ccb); } int ahci_ata_cmd(struct ata_xfer *xa) { struct ahci_ccb *ccb = (struct ahci_ccb *)xa; struct ahci_cmd_hdr *cmd_slot; int s; KASSERT(xa->state == ATA_S_SETUP); if (ccb->ccb_port->ap_state == AP_S_FATAL_ERROR) goto failcmd; ccb->ccb_done = ahci_ata_cmd_done; cmd_slot = ccb->ccb_cmd_hdr; cmd_slot->flags = htole16(5); /* FIS length (in DWORDs) */ if (xa->flags & ATA_F_WRITE) cmd_slot->flags |= htole16(AHCI_CMD_LIST_FLAG_W); if (xa->flags & ATA_F_PACKET) cmd_slot->flags |= htole16(AHCI_CMD_LIST_FLAG_A); if (ahci_load_prdt(ccb) != 0) goto failcmd; timeout_set(&xa->stimeout, ahci_ata_cmd_timeout, ccb); xa->state = ATA_S_PENDING; if (xa->flags & ATA_F_POLL) { ahci_poll(ccb, xa->timeout, ahci_ata_cmd_timeout); return (ATA_COMPLETE); } timeout_add_msec(&xa->stimeout, xa->timeout); s = splbio(); ahci_start(ccb); splx(s); return (ATA_QUEUED); failcmd: s = splbio(); xa->state = ATA_S_ERROR; xa->complete(xa); splx(s); return (ATA_ERROR); } void ahci_ata_cmd_done(struct ahci_ccb *ccb) { struct ata_xfer *xa = &ccb->ccb_xa; timeout_del(&xa->stimeout); if (xa->state == ATA_S_ONCHIP || xa->state == ATA_S_ERROR) ahci_issue_pending_commands(ccb->ccb_port, xa->flags & ATA_F_NCQ); ahci_unload_prdt(ccb); if (xa->state == ATA_S_ONCHIP) xa->state = ATA_S_COMPLETE; #ifdef DIAGNOSTIC else if (xa->state != ATA_S_ERROR && xa->state != ATA_S_TIMEOUT) printf("%s: invalid ata_xfer state %02x in ahci_ata_cmd_done, " "slot %d\n", PORTNAME(ccb->ccb_port), xa->state, ccb->ccb_slot); #endif if (xa->state != ATA_S_TIMEOUT) xa->complete(xa); } void ahci_ata_cmd_timeout(void *arg) { struct ahci_ccb *ccb = arg; struct ata_xfer *xa = &ccb->ccb_xa; struct ahci_port *ap = ccb->ccb_port; int s, ccb_was_started, ncq_cmd; volatile u_int32_t *active; s = splbio(); ncq_cmd = (xa->flags & ATA_F_NCQ); active = ncq_cmd ? &ap->ap_sactive : &ap->ap_active; if (ccb->ccb_xa.state == ATA_S_PENDING) { DPRINTF(AHCI_D_TIMEOUT, "%s: command for slot %d timed out " "before it got on chip\n", PORTNAME(ap), ccb->ccb_slot); TAILQ_REMOVE(&ap->ap_ccb_pending, ccb, ccb_entry); ccb_was_started = 0; } else if (ccb->ccb_xa.state == ATA_S_ONCHIP && ahci_port_intr(ap, 1 << ccb->ccb_slot)) { DPRINTF(AHCI_D_TIMEOUT, "%s: final poll of port completed " "command in slot %d\n", PORTNAME(ap), ccb->ccb_slot); goto ret; } else if (ccb->ccb_xa.state != ATA_S_ONCHIP) { DPRINTF(AHCI_D_TIMEOUT, "%s: command slot %d already " "handled%s\n", PORTNAME(ap), ccb->ccb_slot, ISSET(*active, 1 << ccb->ccb_slot) ? " but slot is still active?" : "."); goto ret; } else if (!ISSET(ahci_pread(ap, ncq_cmd ? AHCI_PREG_SACT : AHCI_PREG_CI), 1 << ccb->ccb_slot) && ISSET(*active, 1 << ccb->ccb_slot)) { DPRINTF(AHCI_D_TIMEOUT, "%s: command slot %d completed but " "IRQ handler didn't detect it. Why?\n", PORTNAME(ap), ccb->ccb_slot); *active &= ~(1 << ccb->ccb_slot); ccb->ccb_done(ccb); goto ret; } else { ccb_was_started = 1; } /* Complete the slot with a timeout error. */ ccb->ccb_xa.state = ATA_S_TIMEOUT; *active &= ~(1 << ccb->ccb_slot); DPRINTF(AHCI_D_TIMEOUT, "%s: run completion (1)\n", PORTNAME(ap)); ccb->ccb_done(ccb); /* This won't issue pending commands or run the atascsi completion. */ /* Reset port to abort running command. */ if (ccb_was_started) { DPRINTF(AHCI_D_TIMEOUT, "%s: resetting port to abort%s command " "in slot %d, active %08x\n", PORTNAME(ap), ncq_cmd ? " NCQ" : "", ccb->ccb_slot, *active); if (ahci_port_softreset(ap) != 0 && ahci_port_portreset(ap) != 0) { printf("%s: failed to reset port during timeout " "handling, disabling it\n", PORTNAME(ap)); ap->ap_state = AP_S_FATAL_ERROR; } /* Restart any other commands that were aborted by the reset. */ if (*active) { DPRINTF(AHCI_D_TIMEOUT, "%s: re-enabling%s slots " "%08x\n", PORTNAME(ap), ncq_cmd ? " NCQ" : "", *active); if (ncq_cmd) ahci_pwrite(ap, AHCI_PREG_SACT, *active); ahci_pwrite(ap, AHCI_PREG_CI, *active); } } /* Issue any pending commands now. */ DPRINTF(AHCI_D_TIMEOUT, "%s: issue pending\n", PORTNAME(ap)); if (ccb_was_started) ahci_issue_pending_commands(ap, ncq_cmd); else if (ap->ap_active == 0) ahci_issue_pending_ncq_commands(ap); /* Complete the timed out ata_xfer I/O (may generate new I/O). */ DPRINTF(AHCI_D_TIMEOUT, "%s: run completion (2)\n", PORTNAME(ap)); xa->complete(xa); DPRINTF(AHCI_D_TIMEOUT, "%s: splx\n", PORTNAME(ap)); ret: splx(s); } void ahci_empty_done(struct ahci_ccb *ccb) { ccb->ccb_xa.state = ATA_S_COMPLETE; }