/* * Driver for IBM PowerNV 842 compression accelerator * * Copyright (C) 2015 Dan Streetman, IBM Corp * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include "nx-842.h" #include #include #include #include #include MODULE_LICENSE("GPL"); MODULE_AUTHOR("Dan Streetman "); MODULE_DESCRIPTION("842 H/W Compression driver for IBM PowerNV processors"); MODULE_ALIAS_CRYPTO("842"); MODULE_ALIAS_CRYPTO("842-nx"); #define WORKMEM_ALIGN (CRB_ALIGN) #define CSB_WAIT_MAX (5000) /* ms */ #define VAS_RETRIES (10) /* # of requests allowed per RxFIFO at a time. 0 for unlimited */ #define MAX_CREDITS_PER_RXFIFO (1024) struct nx842_workmem { /* Below fields must be properly aligned */ struct coprocessor_request_block crb; /* CRB_ALIGN align */ struct data_descriptor_entry ddl_in[DDL_LEN_MAX]; /* DDE_ALIGN align */ struct data_descriptor_entry ddl_out[DDL_LEN_MAX]; /* DDE_ALIGN align */ /* Above fields must be properly aligned */ ktime_t start; struct vas_window *txwin; /* Used with VAS function */ char padding[WORKMEM_ALIGN]; /* unused, to allow alignment */ } __packed __aligned(WORKMEM_ALIGN); struct nx842_coproc { unsigned int chip_id; unsigned int ct; unsigned int ci; /* Coprocessor instance, used with icswx */ struct { struct vas_window *rxwin; int id; } vas; struct list_head list; }; /* * Send the request to NX engine on the chip for the corresponding CPU * where the process is executing. Use with VAS function. */ static DEFINE_PER_CPU(struct nx842_coproc *, coproc_inst); /* no cpu hotplug on powernv, so this list never changes after init */ static LIST_HEAD(nx842_coprocs); static unsigned int nx842_ct; /* used in icswx function */ static int (*nx842_powernv_exec)(const unsigned char *in, unsigned int inlen, unsigned char *out, unsigned int *outlenp, void *workmem, int fc); /** * setup_indirect_dde - Setup an indirect DDE * * The DDE is setup with the the DDE count, byte count, and address of * first direct DDE in the list. */ static void setup_indirect_dde(struct data_descriptor_entry *dde, struct data_descriptor_entry *ddl, unsigned int dde_count, unsigned int byte_count) { dde->flags = 0; dde->count = dde_count; dde->index = 0; dde->length = cpu_to_be32(byte_count); dde->address = cpu_to_be64(nx842_get_pa(ddl)); } /** * setup_direct_dde - Setup single DDE from buffer * * The DDE is setup with the buffer and length. The buffer must be properly * aligned. The used length is returned. * Returns: * N Successfully set up DDE with N bytes */ static unsigned int setup_direct_dde(struct data_descriptor_entry *dde, unsigned long pa, unsigned int len) { unsigned int l = min_t(unsigned int, len, LEN_ON_PAGE(pa)); dde->flags = 0; dde->count = 0; dde->index = 0; dde->length = cpu_to_be32(l); dde->address = cpu_to_be64(pa); return l; } /** * setup_ddl - Setup DDL from buffer * * Returns: * 0 Successfully set up DDL */ static int setup_ddl(struct data_descriptor_entry *dde, struct data_descriptor_entry *ddl, unsigned char *buf, unsigned int len, bool in) { unsigned long pa = nx842_get_pa(buf); int i, ret, total_len = len; if (!IS_ALIGNED(pa, DDE_BUFFER_ALIGN)) { pr_debug("%s buffer pa 0x%lx not 0x%x-byte aligned\n", in ? "input" : "output", pa, DDE_BUFFER_ALIGN); return -EINVAL; } /* only need to check last mult; since buffer must be * DDE_BUFFER_ALIGN aligned, and that is a multiple of * DDE_BUFFER_SIZE_MULT, and pre-last page DDE buffers * are guaranteed a multiple of DDE_BUFFER_SIZE_MULT. */ if (len % DDE_BUFFER_LAST_MULT) { pr_debug("%s buffer len 0x%x not a multiple of 0x%x\n", in ? "input" : "output", len, DDE_BUFFER_LAST_MULT); if (in) return -EINVAL; len = round_down(len, DDE_BUFFER_LAST_MULT); } /* use a single direct DDE */ if (len <= LEN_ON_PAGE(pa)) { ret = setup_direct_dde(dde, pa, len); WARN_ON(ret < len); return 0; } /* use the DDL */ for (i = 0; i < DDL_LEN_MAX && len > 0; i++) { ret = setup_direct_dde(&ddl[i], pa, len); buf += ret; len -= ret; pa = nx842_get_pa(buf); } if (len > 0) { pr_debug("0x%x total %s bytes 0x%x too many for DDL.\n", total_len, in ? "input" : "output", len); if (in) return -EMSGSIZE; total_len -= len; } setup_indirect_dde(dde, ddl, i, total_len); return 0; } #define CSB_ERR(csb, msg, ...) \ pr_err("ERROR: " msg " : %02x %02x %02x %02x %08x\n", \ ##__VA_ARGS__, (csb)->flags, \ (csb)->cs, (csb)->cc, (csb)->ce, \ be32_to_cpu((csb)->count)) #define CSB_ERR_ADDR(csb, msg, ...) \ CSB_ERR(csb, msg " at %lx", ##__VA_ARGS__, \ (unsigned long)be64_to_cpu((csb)->address)) /** * wait_for_csb */ static int wait_for_csb(struct nx842_workmem *wmem, struct coprocessor_status_block *csb) { ktime_t start = wmem->start, now = ktime_get(); ktime_t timeout = ktime_add_ms(start, CSB_WAIT_MAX); while (!(READ_ONCE(csb->flags) & CSB_V)) { cpu_relax(); now = ktime_get(); if (ktime_after(now, timeout)) break; } /* hw has updated csb and output buffer */ barrier(); /* check CSB flags */ if (!(csb->flags & CSB_V)) { CSB_ERR(csb, "CSB still not valid after %ld us, giving up", (long)ktime_us_delta(now, start)); return -ETIMEDOUT; } if (csb->flags & CSB_F) { CSB_ERR(csb, "Invalid CSB format"); return -EPROTO; } if (csb->flags & CSB_CH) { CSB_ERR(csb, "Invalid CSB chaining state"); return -EPROTO; } /* verify CSB completion sequence is 0 */ if (csb->cs) { CSB_ERR(csb, "Invalid CSB completion sequence"); return -EPROTO; } /* check CSB Completion Code */ switch (csb->cc) { /* no error */ case CSB_CC_SUCCESS: break; case CSB_CC_TPBC_GT_SPBC: /* not an error, but the compressed data is * larger than the uncompressed data :( */ break; /* input data errors */ case CSB_CC_OPERAND_OVERLAP: /* input and output buffers overlap */ CSB_ERR(csb, "Operand Overlap error"); return -EINVAL; case CSB_CC_INVALID_OPERAND: CSB_ERR(csb, "Invalid operand"); return -EINVAL; case CSB_CC_NOSPC: /* output buffer too small */ return -ENOSPC; case CSB_CC_ABORT: CSB_ERR(csb, "Function aborted"); return -EINTR; case CSB_CC_CRC_MISMATCH: CSB_ERR(csb, "CRC mismatch"); return -EINVAL; case CSB_CC_TEMPL_INVALID: CSB_ERR(csb, "Compressed data template invalid"); return -EINVAL; case CSB_CC_TEMPL_OVERFLOW: CSB_ERR(csb, "Compressed data template shows data past end"); return -EINVAL; case CSB_CC_EXCEED_BYTE_COUNT: /* P9 or later */ /* * DDE byte count exceeds the limit specified in Maximum * byte count register. */ CSB_ERR(csb, "DDE byte count exceeds the limit"); return -EINVAL; /* these should not happen */ case CSB_CC_INVALID_ALIGN: /* setup_ddl should have detected this */ CSB_ERR_ADDR(csb, "Invalid alignment"); return -EINVAL; case CSB_CC_DATA_LENGTH: /* setup_ddl should have detected this */ CSB_ERR(csb, "Invalid data length"); return -EINVAL; case CSB_CC_WR_TRANSLATION: case CSB_CC_TRANSLATION: case CSB_CC_TRANSLATION_DUP1: case CSB_CC_TRANSLATION_DUP2: case CSB_CC_TRANSLATION_DUP3: case CSB_CC_TRANSLATION_DUP4: case CSB_CC_TRANSLATION_DUP5: case CSB_CC_TRANSLATION_DUP6: /* should not happen, we use physical addrs */ CSB_ERR_ADDR(csb, "Translation error"); return -EPROTO; case CSB_CC_WR_PROTECTION: case CSB_CC_PROTECTION: case CSB_CC_PROTECTION_DUP1: case CSB_CC_PROTECTION_DUP2: case CSB_CC_PROTECTION_DUP3: case CSB_CC_PROTECTION_DUP4: case CSB_CC_PROTECTION_DUP5: case CSB_CC_PROTECTION_DUP6: /* should not happen, we use physical addrs */ CSB_ERR_ADDR(csb, "Protection error"); return -EPROTO; case CSB_CC_PRIVILEGE: /* shouldn't happen, we're in HYP mode */ CSB_ERR(csb, "Insufficient Privilege error"); return -EPROTO; case CSB_CC_EXCESSIVE_DDE: /* shouldn't happen, setup_ddl doesn't use many dde's */ CSB_ERR(csb, "Too many DDEs in DDL"); return -EINVAL; case CSB_CC_TRANSPORT: case CSB_CC_INVALID_CRB: /* P9 or later */ /* shouldn't happen, we setup CRB correctly */ CSB_ERR(csb, "Invalid CRB"); return -EINVAL; case CSB_CC_INVALID_DDE: /* P9 or later */ /* * shouldn't happen, setup_direct/indirect_dde creates * DDE right */ CSB_ERR(csb, "Invalid DDE"); return -EINVAL; case CSB_CC_SEGMENTED_DDL: /* shouldn't happen, setup_ddl creates DDL right */ CSB_ERR(csb, "Segmented DDL error"); return -EINVAL; case CSB_CC_DDE_OVERFLOW: /* shouldn't happen, setup_ddl creates DDL right */ CSB_ERR(csb, "DDE overflow error"); return -EINVAL; case CSB_CC_SESSION: /* should not happen with ICSWX */ CSB_ERR(csb, "Session violation error"); return -EPROTO; case CSB_CC_CHAIN: /* should not happen, we don't use chained CRBs */ CSB_ERR(csb, "Chained CRB error"); return -EPROTO; case CSB_CC_SEQUENCE: /* should not happen, we don't use chained CRBs */ CSB_ERR(csb, "CRB seqeunce number error"); return -EPROTO; case CSB_CC_UNKNOWN_CODE: CSB_ERR(csb, "Unknown subfunction code"); return -EPROTO; /* hardware errors */ case CSB_CC_RD_EXTERNAL: case CSB_CC_RD_EXTERNAL_DUP1: case CSB_CC_RD_EXTERNAL_DUP2: case CSB_CC_RD_EXTERNAL_DUP3: CSB_ERR_ADDR(csb, "Read error outside coprocessor"); return -EPROTO; case CSB_CC_WR_EXTERNAL: CSB_ERR_ADDR(csb, "Write error outside coprocessor"); return -EPROTO; case CSB_CC_INTERNAL: CSB_ERR(csb, "Internal error in coprocessor"); return -EPROTO; case CSB_CC_PROVISION: CSB_ERR(csb, "Storage provision error"); return -EPROTO; case CSB_CC_HW: CSB_ERR(csb, "Correctable hardware error"); return -EPROTO; case CSB_CC_HW_EXPIRED_TIMER: /* P9 or later */ CSB_ERR(csb, "Job did not finish within allowed time"); return -EPROTO; default: CSB_ERR(csb, "Invalid CC %d", csb->cc); return -EPROTO; } /* check Completion Extension state */ if (csb->ce & CSB_CE_TERMINATION) { CSB_ERR(csb, "CSB request was terminated"); return -EPROTO; } if (csb->ce & CSB_CE_INCOMPLETE) { CSB_ERR(csb, "CSB request not complete"); return -EPROTO; } if (!(csb->ce & CSB_CE_TPBC)) { CSB_ERR(csb, "TPBC not provided, unknown target length"); return -EPROTO; } /* successful completion */ pr_debug_ratelimited("Processed %u bytes in %lu us\n", be32_to_cpu(csb->count), (unsigned long)ktime_us_delta(now, start)); return 0; } static int nx842_config_crb(const unsigned char *in, unsigned int inlen, unsigned char *out, unsigned int outlen, struct nx842_workmem *wmem) { struct coprocessor_request_block *crb; struct coprocessor_status_block *csb; u64 csb_addr; int ret; crb = &wmem->crb; csb = &crb->csb; /* Clear any previous values */ memset(crb, 0, sizeof(*crb)); /* set up DDLs */ ret = setup_ddl(&crb->source, wmem->ddl_in, (unsigned char *)in, inlen, true); if (ret) return ret; ret = setup_ddl(&crb->target, wmem->ddl_out, out, outlen, false); if (ret) return ret; /* set up CRB's CSB addr */ csb_addr = nx842_get_pa(csb) & CRB_CSB_ADDRESS; csb_addr |= CRB_CSB_AT; /* Addrs are phys */ crb->csb_addr = cpu_to_be64(csb_addr); return 0; } /** * nx842_exec_icswx - compress/decompress data using the 842 algorithm * * (De)compression provided by the NX842 coprocessor on IBM PowerNV systems. * This compresses or decompresses the provided input buffer into the provided * output buffer. * * Upon return from this function @outlen contains the length of the * output data. If there is an error then @outlen will be 0 and an * error will be specified by the return code from this function. * * The @workmem buffer should only be used by one function call at a time. * * @in: input buffer pointer * @inlen: input buffer size * @out: output buffer pointer * @outlenp: output buffer size pointer * @workmem: working memory buffer pointer, size determined by * nx842_powernv_driver.workmem_size * @fc: function code, see CCW Function Codes in nx-842.h * * Returns: * 0 Success, output of length @outlenp stored in the buffer at @out * -ENODEV Hardware unavailable * -ENOSPC Output buffer is to small * -EMSGSIZE Input buffer too large * -EINVAL buffer constraints do not fix nx842_constraints * -EPROTO hardware error during operation * -ETIMEDOUT hardware did not complete operation in reasonable time * -EINTR operation was aborted */ static int nx842_exec_icswx(const unsigned char *in, unsigned int inlen, unsigned char *out, unsigned int *outlenp, void *workmem, int fc) { struct coprocessor_request_block *crb; struct coprocessor_status_block *csb; struct nx842_workmem *wmem; int ret; u32 ccw; unsigned int outlen = *outlenp; wmem = PTR_ALIGN(workmem, WORKMEM_ALIGN); *outlenp = 0; /* shoudn't happen, we don't load without a coproc */ if (!nx842_ct) { pr_err_ratelimited("coprocessor CT is 0"); return -ENODEV; } ret = nx842_config_crb(in, inlen, out, outlen, wmem); if (ret) return ret; crb = &wmem->crb; csb = &crb->csb; /* set up CCW */ ccw = 0; ccw = SET_FIELD(CCW_CT, ccw, nx842_ct); ccw = SET_FIELD(CCW_CI_842, ccw, 0); /* use 0 for hw auto-selection */ ccw = SET_FIELD(CCW_FC_842, ccw, fc); wmem->start = ktime_get(); /* do ICSWX */ ret = icswx(cpu_to_be32(ccw), crb); pr_debug_ratelimited("icswx CR %x ccw %x crb->ccw %x\n", ret, (unsigned int)ccw, (unsigned int)be32_to_cpu(crb->ccw)); /* * NX842 coprocessor sets 3rd bit in CR register with XER[S0]. * XER[S0] is the integer summary overflow bit which is nothing * to do NX. Since this bit can be set with other return values, * mask this bit. */ ret &= ~ICSWX_XERS0; switch (ret) { case ICSWX_INITIATED: ret = wait_for_csb(wmem, csb); break; case ICSWX_BUSY: pr_debug_ratelimited("842 Coprocessor busy\n"); ret = -EBUSY; break; case ICSWX_REJECTED: pr_err_ratelimited("ICSWX rejected\n"); ret = -EPROTO; break; } if (!ret) *outlenp = be32_to_cpu(csb->count); return ret; } /** * nx842_exec_vas - compress/decompress data using the 842 algorithm * * (De)compression provided by the NX842 coprocessor on IBM PowerNV systems. * This compresses or decompresses the provided input buffer into the provided * output buffer. * * Upon return from this function @outlen contains the length of the * output data. If there is an error then @outlen will be 0 and an * error will be specified by the return code from this function. * * The @workmem buffer should only be used by one function call at a time. * * @in: input buffer pointer * @inlen: input buffer size * @out: output buffer pointer * @outlenp: output buffer size pointer * @workmem: working memory buffer pointer, size determined by * nx842_powernv_driver.workmem_size * @fc: function code, see CCW Function Codes in nx-842.h * * Returns: * 0 Success, output of length @outlenp stored in the buffer * at @out * -ENODEV Hardware unavailable * -ENOSPC Output buffer is to small * -EMSGSIZE Input buffer too large * -EINVAL buffer constraints do not fix nx842_constraints * -EPROTO hardware error during operation * -ETIMEDOUT hardware did not complete operation in reasonable time * -EINTR operation was aborted */ static int nx842_exec_vas(const unsigned char *in, unsigned int inlen, unsigned char *out, unsigned int *outlenp, void *workmem, int fc) { struct coprocessor_request_block *crb; struct coprocessor_status_block *csb; struct nx842_workmem *wmem; struct vas_window *txwin; int ret, i = 0; u32 ccw; unsigned int outlen = *outlenp; wmem = PTR_ALIGN(workmem, WORKMEM_ALIGN); *outlenp = 0; crb = &wmem->crb; csb = &crb->csb; ret = nx842_config_crb(in, inlen, out, outlen, wmem); if (ret) return ret; ccw = 0; ccw = SET_FIELD(CCW_FC_842, ccw, fc); crb->ccw = cpu_to_be32(ccw); txwin = wmem->txwin; /* shoudn't happen, we don't load without a coproc */ if (!txwin) { pr_err_ratelimited("NX-842 coprocessor is not available"); return -ENODEV; } do { wmem->start = ktime_get(); preempt_disable(); /* * VAS copy CRB into L2 cache. Refer . * @crb and @offset. */ vas_copy_crb(crb, 0); /* * VAS paste previously copied CRB to NX. * @txwin, @offset and @last (must be true). */ ret = vas_paste_crb(txwin, 0, 1); preempt_enable(); /* * Retry copy/paste function for VAS failures. */ } while (ret && (i++ < VAS_RETRIES)); if (ret) { pr_err_ratelimited("VAS copy/paste failed\n"); return ret; } ret = wait_for_csb(wmem, csb); if (!ret) *outlenp = be32_to_cpu(csb->count); return ret; } /** * nx842_powernv_compress - Compress data using the 842 algorithm * * Compression provided by the NX842 coprocessor on IBM PowerNV systems. * The input buffer is compressed and the result is stored in the * provided output buffer. * * Upon return from this function @outlen contains the length of the * compressed data. If there is an error then @outlen will be 0 and an * error will be specified by the return code from this function. * * @in: input buffer pointer * @inlen: input buffer size * @out: output buffer pointer * @outlenp: output buffer size pointer * @workmem: working memory buffer pointer, size determined by * nx842_powernv_driver.workmem_size * * Returns: see @nx842_powernv_exec() */ static int nx842_powernv_compress(const unsigned char *in, unsigned int inlen, unsigned char *out, unsigned int *outlenp, void *wmem) { return nx842_powernv_exec(in, inlen, out, outlenp, wmem, CCW_FC_842_COMP_CRC); } /** * nx842_powernv_decompress - Decompress data using the 842 algorithm * * Decompression provided by the NX842 coprocessor on IBM PowerNV systems. * The input buffer is decompressed and the result is stored in the * provided output buffer. * * Upon return from this function @outlen contains the length of the * decompressed data. If there is an error then @outlen will be 0 and an * error will be specified by the return code from this function. * * @in: input buffer pointer * @inlen: input buffer size * @out: output buffer pointer * @outlenp: output buffer size pointer * @workmem: working memory buffer pointer, size determined by * nx842_powernv_driver.workmem_size * * Returns: see @nx842_powernv_exec() */ static int nx842_powernv_decompress(const unsigned char *in, unsigned int inlen, unsigned char *out, unsigned int *outlenp, void *wmem) { return nx842_powernv_exec(in, inlen, out, outlenp, wmem, CCW_FC_842_DECOMP_CRC); } static inline void nx842_add_coprocs_list(struct nx842_coproc *coproc, int chipid) { coproc->chip_id = chipid; INIT_LIST_HEAD(&coproc->list); list_add(&coproc->list, &nx842_coprocs); } /* * Identify chip ID for each CPU and save coprocesor adddress for the * corresponding NX engine in percpu coproc_inst. * coproc_inst is used in crypto_init to open send window on the NX instance * for the corresponding CPU / chip where the open request is executed. */ static void nx842_set_per_cpu_coproc(struct nx842_coproc *coproc) { unsigned int i, chip_id; for_each_possible_cpu(i) { chip_id = cpu_to_chip_id(i); if (coproc->chip_id == chip_id) per_cpu(coproc_inst, i) = coproc; } } static struct vas_window *nx842_alloc_txwin(struct nx842_coproc *coproc) { struct vas_window *txwin = NULL; struct vas_tx_win_attr txattr; /* * Kernel requests will be high priority. So open send * windows only for high priority RxFIFO entries. */ vas_init_tx_win_attr(&txattr, coproc->ct); txattr.lpid = 0; /* lpid is 0 for kernel requests */ txattr.pid = 0; /* pid is 0 for kernel requests */ /* * Open a VAS send window which is used to send request to NX. */ txwin = vas_tx_win_open(coproc->vas.id, coproc->ct, &txattr); if (IS_ERR(txwin)) { pr_err("ibm,nx-842: Can not open TX window: %ld\n", PTR_ERR(txwin)); return NULL; } return txwin; } static int __init vas_cfg_coproc_info(struct device_node *dn, int chip_id, int vasid) { struct vas_window *rxwin = NULL; struct vas_rx_win_attr rxattr; struct nx842_coproc *coproc; u32 lpid, pid, tid, fifo_size; u64 rx_fifo; const char *priority; int ret; ret = of_property_read_u64(dn, "rx-fifo-address", &rx_fifo); if (ret) { pr_err("Missing rx-fifo-address property\n"); return ret; } ret = of_property_read_u32(dn, "rx-fifo-size", &fifo_size); if (ret) { pr_err("Missing rx-fifo-size property\n"); return ret; } ret = of_property_read_u32(dn, "lpid", &lpid); if (ret) { pr_err("Missing lpid property\n"); return ret; } ret = of_property_read_u32(dn, "pid", &pid); if (ret) { pr_err("Missing pid property\n"); return ret; } ret = of_property_read_u32(dn, "tid", &tid); if (ret) { pr_err("Missing tid property\n"); return ret; } ret = of_property_read_string(dn, "priority", &priority); if (ret) { pr_err("Missing priority property\n"); return ret; } coproc = kzalloc(sizeof(*coproc), GFP_KERNEL); if (!coproc) return -ENOMEM; if (!strcmp(priority, "High")) coproc->ct = VAS_COP_TYPE_842_HIPRI; else if (!strcmp(priority, "Normal")) coproc->ct = VAS_COP_TYPE_842; else { pr_err("Invalid RxFIFO priority value\n"); ret = -EINVAL; goto err_out; } vas_init_rx_win_attr(&rxattr, coproc->ct); rxattr.rx_fifo = (void *)rx_fifo; rxattr.rx_fifo_size = fifo_size; rxattr.lnotify_lpid = lpid; rxattr.lnotify_pid = pid; rxattr.lnotify_tid = tid; rxattr.wcreds_max = MAX_CREDITS_PER_RXFIFO; /* * Open a VAS receice window which is used to configure RxFIFO * for NX. */ rxwin = vas_rx_win_open(vasid, coproc->ct, &rxattr); if (IS_ERR(rxwin)) { ret = PTR_ERR(rxwin); pr_err("setting RxFIFO with VAS failed: %d\n", ret); goto err_out; } coproc->vas.rxwin = rxwin; coproc->vas.id = vasid; nx842_add_coprocs_list(coproc, chip_id); /* * Kernel requests use only high priority FIFOs. So save coproc * info in percpu coproc_inst which will be used to open send * windows for crypto open requests later. */ if (coproc->ct == VAS_COP_TYPE_842_HIPRI) nx842_set_per_cpu_coproc(coproc); return 0; err_out: kfree(coproc); return ret; } static int __init nx842_powernv_probe_vas(struct device_node *pn) { struct device_node *dn; int chip_id, vasid, ret = 0; int nx_fifo_found = 0; chip_id = of_get_ibm_chip_id(pn); if (chip_id < 0) { pr_err("ibm,chip-id missing\n"); return -EINVAL; } for_each_compatible_node(dn, NULL, "ibm,power9-vas-x") { if (of_get_ibm_chip_id(dn) == chip_id) break; } if (!dn) { pr_err("Missing VAS device node\n"); return -EINVAL; } if (of_property_read_u32(dn, "ibm,vas-id", &vasid)) { pr_err("Missing ibm,vas-id device property\n"); of_node_put(dn); return -EINVAL; } of_node_put(dn); for_each_child_of_node(pn, dn) { if (of_device_is_compatible(dn, "ibm,p9-nx-842")) { ret = vas_cfg_coproc_info(dn, chip_id, vasid); if (ret) { of_node_put(dn); return ret; } nx_fifo_found++; } } if (!nx_fifo_found) { pr_err("NX842 FIFO nodes are missing\n"); ret = -EINVAL; } return ret; } static int __init nx842_powernv_probe(struct device_node *dn) { struct nx842_coproc *coproc; unsigned int ct, ci; int chip_id; chip_id = of_get_ibm_chip_id(dn); if (chip_id < 0) { pr_err("ibm,chip-id missing\n"); return -EINVAL; } if (of_property_read_u32(dn, "ibm,842-coprocessor-type", &ct)) { pr_err("ibm,842-coprocessor-type missing\n"); return -EINVAL; } if (of_property_read_u32(dn, "ibm,842-coprocessor-instance", &ci)) { pr_err("ibm,842-coprocessor-instance missing\n"); return -EINVAL; } coproc = kmalloc(sizeof(*coproc), GFP_KERNEL); if (!coproc) return -ENOMEM; coproc->ct = ct; coproc->ci = ci; nx842_add_coprocs_list(coproc, chip_id); pr_info("coprocessor found on chip %d, CT %d CI %d\n", chip_id, ct, ci); if (!nx842_ct) nx842_ct = ct; else if (nx842_ct != ct) pr_err("NX842 chip %d, CT %d != first found CT %d\n", chip_id, ct, nx842_ct); return 0; } static void nx842_delete_coprocs(void) { struct nx842_coproc *coproc, *n; list_for_each_entry_safe(coproc, n, &nx842_coprocs, list) { if (coproc->vas.rxwin) vas_win_close(coproc->vas.rxwin); list_del(&coproc->list); kfree(coproc); } } static struct nx842_constraints nx842_powernv_constraints = { .alignment = DDE_BUFFER_ALIGN, .multiple = DDE_BUFFER_LAST_MULT, .minimum = DDE_BUFFER_LAST_MULT, .maximum = (DDL_LEN_MAX - 1) * PAGE_SIZE, }; static struct nx842_driver nx842_powernv_driver = { .name = KBUILD_MODNAME, .owner = THIS_MODULE, .workmem_size = sizeof(struct nx842_workmem), .constraints = &nx842_powernv_constraints, .compress = nx842_powernv_compress, .decompress = nx842_powernv_decompress, }; static int nx842_powernv_crypto_init_vas(struct crypto_tfm *tfm) { struct nx842_crypto_ctx *ctx = crypto_tfm_ctx(tfm); struct nx842_workmem *wmem; struct nx842_coproc *coproc; int ret; ret = nx842_crypto_init(tfm, &nx842_powernv_driver); if (ret) return ret; wmem = PTR_ALIGN((struct nx842_workmem *)ctx->wmem, WORKMEM_ALIGN); coproc = per_cpu(coproc_inst, smp_processor_id()); ret = -EINVAL; if (coproc && coproc->vas.rxwin) { wmem->txwin = nx842_alloc_txwin(coproc); if (!IS_ERR(wmem->txwin)) return 0; ret = PTR_ERR(wmem->txwin); } return ret; } void nx842_powernv_crypto_exit_vas(struct crypto_tfm *tfm) { struct nx842_crypto_ctx *ctx = crypto_tfm_ctx(tfm); struct nx842_workmem *wmem; wmem = PTR_ALIGN((struct nx842_workmem *)ctx->wmem, WORKMEM_ALIGN); if (wmem && wmem->txwin) vas_win_close(wmem->txwin); nx842_crypto_exit(tfm); } static int nx842_powernv_crypto_init(struct crypto_tfm *tfm) { return nx842_crypto_init(tfm, &nx842_powernv_driver); } static struct crypto_alg nx842_powernv_alg = { .cra_name = "842", .cra_driver_name = "842-nx", .cra_priority = 300, .cra_flags = CRYPTO_ALG_TYPE_COMPRESS, .cra_ctxsize = sizeof(struct nx842_crypto_ctx), .cra_module = THIS_MODULE, .cra_init = nx842_powernv_crypto_init, .cra_exit = nx842_crypto_exit, .cra_u = { .compress = { .coa_compress = nx842_crypto_compress, .coa_decompress = nx842_crypto_decompress } } }; static __init int nx842_powernv_init(void) { struct device_node *dn; int ret; /* verify workmem size/align restrictions */ BUILD_BUG_ON(WORKMEM_ALIGN % CRB_ALIGN); BUILD_BUG_ON(CRB_ALIGN % DDE_ALIGN); BUILD_BUG_ON(CRB_SIZE % DDE_ALIGN); /* verify buffer size/align restrictions */ BUILD_BUG_ON(PAGE_SIZE % DDE_BUFFER_ALIGN); BUILD_BUG_ON(DDE_BUFFER_ALIGN % DDE_BUFFER_SIZE_MULT); BUILD_BUG_ON(DDE_BUFFER_SIZE_MULT % DDE_BUFFER_LAST_MULT); for_each_compatible_node(dn, NULL, "ibm,power9-nx") { ret = nx842_powernv_probe_vas(dn); if (ret) { nx842_delete_coprocs(); return ret; } } if (list_empty(&nx842_coprocs)) { for_each_compatible_node(dn, NULL, "ibm,power-nx") nx842_powernv_probe(dn); if (!nx842_ct) return -ENODEV; nx842_powernv_exec = nx842_exec_icswx; } else { nx842_powernv_exec = nx842_exec_vas; nx842_powernv_alg.cra_init = nx842_powernv_crypto_init_vas; nx842_powernv_alg.cra_exit = nx842_powernv_crypto_exit_vas; } ret = crypto_register_alg(&nx842_powernv_alg); if (ret) { nx842_delete_coprocs(); return ret; } return 0; } module_init(nx842_powernv_init); static void __exit nx842_powernv_exit(void) { crypto_unregister_alg(&nx842_powernv_alg); nx842_delete_coprocs(); } module_exit(nx842_powernv_exit);