Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Prabhjot Khurana | 3920 | 99.87% | 1 | 50.00% |
Wei Yongjun | 5 | 0.13% | 1 | 50.00% |
Total | 3925 | 2 |
// SPDX-License-Identifier: GPL-2.0-only /* * Intel Keem Bay OCS ECC Crypto Driver. * * Copyright (C) 2019-2021 Intel Corporation */ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include <linux/clk.h> #include <linux/completion.h> #include <linux/crypto.h> #include <linux/delay.h> #include <linux/fips.h> #include <linux/interrupt.h> #include <linux/io.h> #include <linux/iopoll.h> #include <linux/irq.h> #include <linux/module.h> #include <linux/of.h> #include <linux/platform_device.h> #include <linux/scatterlist.h> #include <linux/slab.h> #include <linux/types.h> #include <crypto/ecc_curve.h> #include <crypto/ecdh.h> #include <crypto/engine.h> #include <crypto/kpp.h> #include <crypto/rng.h> #include <crypto/internal/ecc.h> #include <crypto/internal/kpp.h> #define DRV_NAME "keembay-ocs-ecc" #define KMB_OCS_ECC_PRIORITY 350 #define HW_OFFS_OCS_ECC_COMMAND 0x00000000 #define HW_OFFS_OCS_ECC_STATUS 0x00000004 #define HW_OFFS_OCS_ECC_DATA_IN 0x00000080 #define HW_OFFS_OCS_ECC_CX_DATA_OUT 0x00000100 #define HW_OFFS_OCS_ECC_CY_DATA_OUT 0x00000180 #define HW_OFFS_OCS_ECC_ISR 0x00000400 #define HW_OFFS_OCS_ECC_IER 0x00000404 #define HW_OCS_ECC_ISR_INT_STATUS_DONE BIT(0) #define HW_OCS_ECC_COMMAND_INS_BP BIT(0) #define HW_OCS_ECC_COMMAND_START_VAL BIT(0) #define OCS_ECC_OP_SIZE_384 BIT(8) #define OCS_ECC_OP_SIZE_256 0 /* ECC Instruction : for ECC_COMMAND */ #define OCS_ECC_INST_WRITE_AX (0x1 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_WRITE_AY (0x2 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_WRITE_BX_D (0x3 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_WRITE_BY_L (0x4 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_WRITE_P (0x5 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_WRITE_A (0x6 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_CALC_D_IDX_A (0x8 << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_CALC_A_POW_B_MODP (0xB << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_CALC_A_MUL_B_MODP (0xC << HW_OCS_ECC_COMMAND_INS_BP) #define OCS_ECC_INST_CALC_A_ADD_B_MODP (0xD << HW_OCS_ECC_COMMAND_INS_BP) #define ECC_ENABLE_INTR 1 #define POLL_USEC 100 #define TIMEOUT_USEC 10000 #define KMB_ECC_VLI_MAX_DIGITS ECC_CURVE_NIST_P384_DIGITS #define KMB_ECC_VLI_MAX_BYTES (KMB_ECC_VLI_MAX_DIGITS \ << ECC_DIGITS_TO_BYTES_SHIFT) #define POW_CUBE 3 /** * struct ocs_ecc_dev - ECC device context * @list: List of device contexts * @dev: OCS ECC device * @base_reg: IO base address of OCS ECC * @engine: Crypto engine for the device * @irq_done: IRQ done completion. * @irq: IRQ number */ struct ocs_ecc_dev { struct list_head list; struct device *dev; void __iomem *base_reg; struct crypto_engine *engine; struct completion irq_done; int irq; }; /** * struct ocs_ecc_ctx - Transformation context. * @engine_ctx: Crypto engine ctx. * @ecc_dev: The ECC driver associated with this context. * @curve: The elliptic curve used by this transformation. * @private_key: The private key. */ struct ocs_ecc_ctx { struct crypto_engine_ctx engine_ctx; struct ocs_ecc_dev *ecc_dev; const struct ecc_curve *curve; u64 private_key[KMB_ECC_VLI_MAX_DIGITS]; }; /* Driver data. */ struct ocs_ecc_drv { struct list_head dev_list; spinlock_t lock; /* Protects dev_list. */ }; /* Global variable holding the list of OCS ECC devices (only one expected). */ static struct ocs_ecc_drv ocs_ecc = { .dev_list = LIST_HEAD_INIT(ocs_ecc.dev_list), .lock = __SPIN_LOCK_UNLOCKED(ocs_ecc.lock), }; /* Get OCS ECC tfm context from kpp_request. */ static inline struct ocs_ecc_ctx *kmb_ocs_ecc_tctx(struct kpp_request *req) { return kpp_tfm_ctx(crypto_kpp_reqtfm(req)); } /* Converts number of digits to number of bytes. */ static inline unsigned int digits_to_bytes(unsigned int n) { return n << ECC_DIGITS_TO_BYTES_SHIFT; } /* * Wait for ECC idle i.e when an operation (other than write operations) * is done. */ static inline int ocs_ecc_wait_idle(struct ocs_ecc_dev *dev) { u32 value; return readl_poll_timeout((dev->base_reg + HW_OFFS_OCS_ECC_STATUS), value, !(value & HW_OCS_ECC_ISR_INT_STATUS_DONE), POLL_USEC, TIMEOUT_USEC); } static void ocs_ecc_cmd_start(struct ocs_ecc_dev *ecc_dev, u32 op_size) { iowrite32(op_size | HW_OCS_ECC_COMMAND_START_VAL, ecc_dev->base_reg + HW_OFFS_OCS_ECC_COMMAND); } /* Direct write of u32 buffer to ECC engine with associated instruction. */ static void ocs_ecc_write_cmd_and_data(struct ocs_ecc_dev *dev, u32 op_size, u32 inst, const void *data_in, size_t data_size) { iowrite32(op_size | inst, dev->base_reg + HW_OFFS_OCS_ECC_COMMAND); /* MMIO Write src uint32 to dst. */ memcpy_toio(dev->base_reg + HW_OFFS_OCS_ECC_DATA_IN, data_in, data_size); } /* Start OCS ECC operation and wait for its completion. */ static int ocs_ecc_trigger_op(struct ocs_ecc_dev *ecc_dev, u32 op_size, u32 inst) { reinit_completion(&ecc_dev->irq_done); iowrite32(ECC_ENABLE_INTR, ecc_dev->base_reg + HW_OFFS_OCS_ECC_IER); iowrite32(op_size | inst, ecc_dev->base_reg + HW_OFFS_OCS_ECC_COMMAND); return wait_for_completion_interruptible(&ecc_dev->irq_done); } /** * ocs_ecc_read_cx_out() - Read the CX data output buffer. * @dev: The OCS ECC device to read from. * @cx_out: The buffer where to store the CX value. Must be at least * @byte_count byte long. * @byte_count: The amount of data to read. */ static inline void ocs_ecc_read_cx_out(struct ocs_ecc_dev *dev, void *cx_out, size_t byte_count) { memcpy_fromio(cx_out, dev->base_reg + HW_OFFS_OCS_ECC_CX_DATA_OUT, byte_count); } /** * ocs_ecc_read_cy_out() - Read the CX data output buffer. * @dev: The OCS ECC device to read from. * @cy_out: The buffer where to store the CY value. Must be at least * @byte_count byte long. * @byte_count: The amount of data to read. */ static inline void ocs_ecc_read_cy_out(struct ocs_ecc_dev *dev, void *cy_out, size_t byte_count) { memcpy_fromio(cy_out, dev->base_reg + HW_OFFS_OCS_ECC_CY_DATA_OUT, byte_count); } static struct ocs_ecc_dev *kmb_ocs_ecc_find_dev(struct ocs_ecc_ctx *tctx) { if (tctx->ecc_dev) return tctx->ecc_dev; spin_lock(&ocs_ecc.lock); /* Only a single OCS device available. */ tctx->ecc_dev = list_first_entry(&ocs_ecc.dev_list, struct ocs_ecc_dev, list); spin_unlock(&ocs_ecc.lock); return tctx->ecc_dev; } /* Do point multiplication using OCS ECC HW. */ static int kmb_ecc_point_mult(struct ocs_ecc_dev *ecc_dev, struct ecc_point *result, const struct ecc_point *point, u64 *scalar, const struct ecc_curve *curve) { u8 sca[KMB_ECC_VLI_MAX_BYTES]; /* Use the maximum data size. */ u32 op_size = (curve->g.ndigits > ECC_CURVE_NIST_P256_DIGITS) ? OCS_ECC_OP_SIZE_384 : OCS_ECC_OP_SIZE_256; size_t nbytes = digits_to_bytes(curve->g.ndigits); int rc = 0; /* Generate random nbytes for Simple and Differential SCA protection. */ rc = crypto_get_default_rng(); if (rc) return rc; rc = crypto_rng_get_bytes(crypto_default_rng, sca, nbytes); crypto_put_default_rng(); if (rc) return rc; /* Wait engine to be idle before starting new operation. */ rc = ocs_ecc_wait_idle(ecc_dev); if (rc) return rc; /* Send ecc_start pulse as well as indicating operation size. */ ocs_ecc_cmd_start(ecc_dev, op_size); /* Write ax param; Base point (Gx). */ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_AX, point->x, nbytes); /* Write ay param; Base point (Gy). */ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_AY, point->y, nbytes); /* * Write the private key into DATA_IN reg. * * Since DATA_IN register is used to write different values during the * computation private Key value is overwritten with * side-channel-resistance value. */ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_BX_D, scalar, nbytes); /* Write operand by/l. */ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_BY_L, sca, nbytes); memzero_explicit(sca, sizeof(sca)); /* Write p = curve prime(GF modulus). */ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_P, curve->p, nbytes); /* Write a = curve coefficient. */ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_A, curve->a, nbytes); /* Make hardware perform the multiplication. */ rc = ocs_ecc_trigger_op(ecc_dev, op_size, OCS_ECC_INST_CALC_D_IDX_A); if (rc) return rc; /* Read result. */ ocs_ecc_read_cx_out(ecc_dev, result->x, nbytes); ocs_ecc_read_cy_out(ecc_dev, result->y, nbytes); return 0; } /** * kmb_ecc_do_scalar_op() - Perform Scalar operation using OCS ECC HW. * @ecc_dev: The OCS ECC device to use. * @scalar_out: Where to store the output scalar. * @scalar_a: Input scalar operand 'a'. * @scalar_b: Input scalar operand 'b' * @curve: The curve on which the operation is performed. * @ndigits: The size of the operands (in digits). * @inst: The operation to perform (as an OCS ECC instruction). * * Return: 0 on success, negative error code otherwise. */ static int kmb_ecc_do_scalar_op(struct ocs_ecc_dev *ecc_dev, u64 *scalar_out, const u64 *scalar_a, const u64 *scalar_b, const struct ecc_curve *curve, unsigned int ndigits, const u32 inst) { u32 op_size = (ndigits > ECC_CURVE_NIST_P256_DIGITS) ? OCS_ECC_OP_SIZE_384 : OCS_ECC_OP_SIZE_256; size_t nbytes = digits_to_bytes(ndigits); int rc; /* Wait engine to be idle before starting new operation. */ rc = ocs_ecc_wait_idle(ecc_dev); if (rc) return rc; /* Send ecc_start pulse as well as indicating operation size. */ ocs_ecc_cmd_start(ecc_dev, op_size); /* Write ax param (Base point (Gx).*/ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_AX, scalar_a, nbytes); /* Write ay param Base point (Gy).*/ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_AY, scalar_b, nbytes); /* Write p = curve prime(GF modulus).*/ ocs_ecc_write_cmd_and_data(ecc_dev, op_size, OCS_ECC_INST_WRITE_P, curve->p, nbytes); /* Give instruction A.B or A+B to ECC engine. */ rc = ocs_ecc_trigger_op(ecc_dev, op_size, inst); if (rc) return rc; ocs_ecc_read_cx_out(ecc_dev, scalar_out, nbytes); if (vli_is_zero(scalar_out, ndigits)) return -EINVAL; return 0; } /* SP800-56A section 5.6.2.3.4 partial verification: ephemeral keys only */ static int kmb_ocs_ecc_is_pubkey_valid_partial(struct ocs_ecc_dev *ecc_dev, const struct ecc_curve *curve, struct ecc_point *pk) { u64 xxx[KMB_ECC_VLI_MAX_DIGITS] = { 0 }; u64 yy[KMB_ECC_VLI_MAX_DIGITS] = { 0 }; u64 w[KMB_ECC_VLI_MAX_DIGITS] = { 0 }; int rc; if (WARN_ON(pk->ndigits != curve->g.ndigits)) return -EINVAL; /* Check 1: Verify key is not the zero point. */ if (ecc_point_is_zero(pk)) return -EINVAL; /* Check 2: Verify key is in the range [0, p-1]. */ if (vli_cmp(curve->p, pk->x, pk->ndigits) != 1) return -EINVAL; if (vli_cmp(curve->p, pk->y, pk->ndigits) != 1) return -EINVAL; /* Check 3: Verify that y^2 == (x^3 + a·x + b) mod p */ /* y^2 */ /* Compute y^2 -> store in yy */ rc = kmb_ecc_do_scalar_op(ecc_dev, yy, pk->y, pk->y, curve, pk->ndigits, OCS_ECC_INST_CALC_A_MUL_B_MODP); if (rc) goto exit; /* x^3 */ /* Assigning w = 3, used for calculating x^3. */ w[0] = POW_CUBE; /* Load the next stage.*/ rc = kmb_ecc_do_scalar_op(ecc_dev, xxx, pk->x, w, curve, pk->ndigits, OCS_ECC_INST_CALC_A_POW_B_MODP); if (rc) goto exit; /* Do a*x -> store in w. */ rc = kmb_ecc_do_scalar_op(ecc_dev, w, curve->a, pk->x, curve, pk->ndigits, OCS_ECC_INST_CALC_A_MUL_B_MODP); if (rc) goto exit; /* Do ax + b == w + b; store in w. */ rc = kmb_ecc_do_scalar_op(ecc_dev, w, w, curve->b, curve, pk->ndigits, OCS_ECC_INST_CALC_A_ADD_B_MODP); if (rc) goto exit; /* x^3 + ax + b == x^3 + w -> store in w. */ rc = kmb_ecc_do_scalar_op(ecc_dev, w, xxx, w, curve, pk->ndigits, OCS_ECC_INST_CALC_A_ADD_B_MODP); if (rc) goto exit; /* Compare y^2 == x^3 + a·x + b. */ rc = vli_cmp(yy, w, pk->ndigits); if (rc) rc = -EINVAL; exit: memzero_explicit(xxx, sizeof(xxx)); memzero_explicit(yy, sizeof(yy)); memzero_explicit(w, sizeof(w)); return rc; } /* SP800-56A section 5.6.2.3.3 full verification */ static int kmb_ocs_ecc_is_pubkey_valid_full(struct ocs_ecc_dev *ecc_dev, const struct ecc_curve *curve, struct ecc_point *pk) { struct ecc_point *nQ; int rc; /* Checks 1 through 3 */ rc = kmb_ocs_ecc_is_pubkey_valid_partial(ecc_dev, curve, pk); if (rc) return rc; /* Check 4: Verify that nQ is the zero point. */ nQ = ecc_alloc_point(pk->ndigits); if (!nQ) return -ENOMEM; rc = kmb_ecc_point_mult(ecc_dev, nQ, pk, curve->n, curve); if (rc) goto exit; if (!ecc_point_is_zero(nQ)) rc = -EINVAL; exit: ecc_free_point(nQ); return rc; } static int kmb_ecc_is_key_valid(const struct ecc_curve *curve, const u64 *private_key, size_t private_key_len) { size_t ndigits = curve->g.ndigits; u64 one[KMB_ECC_VLI_MAX_DIGITS] = {1}; u64 res[KMB_ECC_VLI_MAX_DIGITS]; if (private_key_len != digits_to_bytes(ndigits)) return -EINVAL; if (!private_key) return -EINVAL; /* Make sure the private key is in the range [2, n-3]. */ if (vli_cmp(one, private_key, ndigits) != -1) return -EINVAL; vli_sub(res, curve->n, one, ndigits); vli_sub(res, res, one, ndigits); if (vli_cmp(res, private_key, ndigits) != 1) return -EINVAL; return 0; } /* * ECC private keys are generated using the method of extra random bits, * equivalent to that described in FIPS 186-4, Appendix B.4.1. * * d = (c mod(n–1)) + 1 where c is a string of random bits, 64 bits longer * than requested * 0 <= c mod(n-1) <= n-2 and implies that * 1 <= d <= n-1 * * This method generates a private key uniformly distributed in the range * [1, n-1]. */ static int kmb_ecc_gen_privkey(const struct ecc_curve *curve, u64 *privkey) { size_t nbytes = digits_to_bytes(curve->g.ndigits); u64 priv[KMB_ECC_VLI_MAX_DIGITS]; size_t nbits; int rc; nbits = vli_num_bits(curve->n, curve->g.ndigits); /* Check that N is included in Table 1 of FIPS 186-4, section 6.1.1 */ if (nbits < 160 || curve->g.ndigits > ARRAY_SIZE(priv)) return -EINVAL; /* * FIPS 186-4 recommends that the private key should be obtained from a * RBG with a security strength equal to or greater than the security * strength associated with N. * * The maximum security strength identified by NIST SP800-57pt1r4 for * ECC is 256 (N >= 512). * * This condition is met by the default RNG because it selects a favored * DRBG with a security strength of 256. */ if (crypto_get_default_rng()) return -EFAULT; rc = crypto_rng_get_bytes(crypto_default_rng, (u8 *)priv, nbytes); crypto_put_default_rng(); if (rc) goto cleanup; rc = kmb_ecc_is_key_valid(curve, priv, nbytes); if (rc) goto cleanup; ecc_swap_digits(priv, privkey, curve->g.ndigits); cleanup: memzero_explicit(&priv, sizeof(priv)); return rc; } static int kmb_ocs_ecdh_set_secret(struct crypto_kpp *tfm, const void *buf, unsigned int len) { struct ocs_ecc_ctx *tctx = kpp_tfm_ctx(tfm); struct ecdh params; int rc = 0; rc = crypto_ecdh_decode_key(buf, len, ¶ms); if (rc) goto cleanup; /* Ensure key size is not bigger then expected. */ if (params.key_size > digits_to_bytes(tctx->curve->g.ndigits)) { rc = -EINVAL; goto cleanup; } /* Auto-generate private key is not provided. */ if (!params.key || !params.key_size) { rc = kmb_ecc_gen_privkey(tctx->curve, tctx->private_key); goto cleanup; } rc = kmb_ecc_is_key_valid(tctx->curve, (const u64 *)params.key, params.key_size); if (rc) goto cleanup; ecc_swap_digits((const u64 *)params.key, tctx->private_key, tctx->curve->g.ndigits); cleanup: memzero_explicit(¶ms, sizeof(params)); if (rc) tctx->curve = NULL; return rc; } /* Compute shared secret. */ static int kmb_ecc_do_shared_secret(struct ocs_ecc_ctx *tctx, struct kpp_request *req) { struct ocs_ecc_dev *ecc_dev = tctx->ecc_dev; const struct ecc_curve *curve = tctx->curve; u64 shared_secret[KMB_ECC_VLI_MAX_DIGITS]; u64 pubk_buf[KMB_ECC_VLI_MAX_DIGITS * 2]; size_t copied, nbytes, pubk_len; struct ecc_point *pk, *result; int rc; nbytes = digits_to_bytes(curve->g.ndigits); /* Public key is a point, thus it has two coordinates */ pubk_len = 2 * nbytes; /* Copy public key from SG list to pubk_buf. */ copied = sg_copy_to_buffer(req->src, sg_nents_for_len(req->src, pubk_len), pubk_buf, pubk_len); if (copied != pubk_len) return -EINVAL; /* Allocate and initialize public key point. */ pk = ecc_alloc_point(curve->g.ndigits); if (!pk) return -ENOMEM; ecc_swap_digits(pubk_buf, pk->x, curve->g.ndigits); ecc_swap_digits(&pubk_buf[curve->g.ndigits], pk->y, curve->g.ndigits); /* * Check the public key for following * Check 1: Verify key is not the zero point. * Check 2: Verify key is in the range [1, p-1]. * Check 3: Verify that y^2 == (x^3 + a·x + b) mod p */ rc = kmb_ocs_ecc_is_pubkey_valid_partial(ecc_dev, curve, pk); if (rc) goto exit_free_pk; /* Allocate point for storing computed shared secret. */ result = ecc_alloc_point(pk->ndigits); if (!result) { rc = -ENOMEM; goto exit_free_pk; } /* Calculate the shared secret.*/ rc = kmb_ecc_point_mult(ecc_dev, result, pk, tctx->private_key, curve); if (rc) goto exit_free_result; if (ecc_point_is_zero(result)) { rc = -EFAULT; goto exit_free_result; } /* Copy shared secret from point to buffer. */ ecc_swap_digits(result->x, shared_secret, result->ndigits); /* Request might ask for less bytes than what we have. */ nbytes = min_t(size_t, nbytes, req->dst_len); copied = sg_copy_from_buffer(req->dst, sg_nents_for_len(req->dst, nbytes), shared_secret, nbytes); if (copied != nbytes) rc = -EINVAL; memzero_explicit(shared_secret, sizeof(shared_secret)); exit_free_result: ecc_free_point(result); exit_free_pk: ecc_free_point(pk); return rc; } /* Compute public key. */ static int kmb_ecc_do_public_key(struct ocs_ecc_ctx *tctx, struct kpp_request *req) { const struct ecc_curve *curve = tctx->curve; u64 pubk_buf[KMB_ECC_VLI_MAX_DIGITS * 2]; struct ecc_point *pk; size_t pubk_len; size_t copied; int rc; /* Public key is a point, so it has double the digits. */ pubk_len = 2 * digits_to_bytes(curve->g.ndigits); pk = ecc_alloc_point(curve->g.ndigits); if (!pk) return -ENOMEM; /* Public Key(pk) = priv * G. */ rc = kmb_ecc_point_mult(tctx->ecc_dev, pk, &curve->g, tctx->private_key, curve); if (rc) goto exit; /* SP800-56A rev 3 5.6.2.1.3 key check */ if (kmb_ocs_ecc_is_pubkey_valid_full(tctx->ecc_dev, curve, pk)) { rc = -EAGAIN; goto exit; } /* Copy public key from point to buffer. */ ecc_swap_digits(pk->x, pubk_buf, pk->ndigits); ecc_swap_digits(pk->y, &pubk_buf[pk->ndigits], pk->ndigits); /* Copy public key to req->dst. */ copied = sg_copy_from_buffer(req->dst, sg_nents_for_len(req->dst, pubk_len), pubk_buf, pubk_len); if (copied != pubk_len) rc = -EINVAL; exit: ecc_free_point(pk); return rc; } static int kmb_ocs_ecc_do_one_request(struct crypto_engine *engine, void *areq) { struct kpp_request *req = container_of(areq, struct kpp_request, base); struct ocs_ecc_ctx *tctx = kmb_ocs_ecc_tctx(req); struct ocs_ecc_dev *ecc_dev = tctx->ecc_dev; int rc; if (req->src) rc = kmb_ecc_do_shared_secret(tctx, req); else rc = kmb_ecc_do_public_key(tctx, req); crypto_finalize_kpp_request(ecc_dev->engine, req, rc); return 0; } static int kmb_ocs_ecdh_generate_public_key(struct kpp_request *req) { struct ocs_ecc_ctx *tctx = kmb_ocs_ecc_tctx(req); const struct ecc_curve *curve = tctx->curve; /* Ensure kmb_ocs_ecdh_set_secret() has been successfully called. */ if (!tctx->curve) return -EINVAL; /* Ensure dst is present. */ if (!req->dst) return -EINVAL; /* Check the request dst is big enough to hold the public key. */ if (req->dst_len < (2 * digits_to_bytes(curve->g.ndigits))) return -EINVAL; /* 'src' is not supposed to be present when generate pubk is called. */ if (req->src) return -EINVAL; return crypto_transfer_kpp_request_to_engine(tctx->ecc_dev->engine, req); } static int kmb_ocs_ecdh_compute_shared_secret(struct kpp_request *req) { struct ocs_ecc_ctx *tctx = kmb_ocs_ecc_tctx(req); const struct ecc_curve *curve = tctx->curve; /* Ensure kmb_ocs_ecdh_set_secret() has been successfully called. */ if (!tctx->curve) return -EINVAL; /* Ensure dst is present. */ if (!req->dst) return -EINVAL; /* Ensure src is present. */ if (!req->src) return -EINVAL; /* * req->src is expected to the (other-side) public key, so its length * must be 2 * coordinate size (in bytes). */ if (req->src_len != 2 * digits_to_bytes(curve->g.ndigits)) return -EINVAL; return crypto_transfer_kpp_request_to_engine(tctx->ecc_dev->engine, req); } static int kmb_ecc_tctx_init(struct ocs_ecc_ctx *tctx, unsigned int curve_id) { memset(tctx, 0, sizeof(*tctx)); tctx->ecc_dev = kmb_ocs_ecc_find_dev(tctx); if (IS_ERR(tctx->ecc_dev)) { pr_err("Failed to find the device : %ld\n", PTR_ERR(tctx->ecc_dev)); return PTR_ERR(tctx->ecc_dev); } tctx->curve = ecc_get_curve(curve_id); if (!tctx->curve) return -EOPNOTSUPP; tctx->engine_ctx.op.prepare_request = NULL; tctx->engine_ctx.op.do_one_request = kmb_ocs_ecc_do_one_request; tctx->engine_ctx.op.unprepare_request = NULL; return 0; } static int kmb_ocs_ecdh_nist_p256_init_tfm(struct crypto_kpp *tfm) { struct ocs_ecc_ctx *tctx = kpp_tfm_ctx(tfm); return kmb_ecc_tctx_init(tctx, ECC_CURVE_NIST_P256); } static int kmb_ocs_ecdh_nist_p384_init_tfm(struct crypto_kpp *tfm) { struct ocs_ecc_ctx *tctx = kpp_tfm_ctx(tfm); return kmb_ecc_tctx_init(tctx, ECC_CURVE_NIST_P384); } static void kmb_ocs_ecdh_exit_tfm(struct crypto_kpp *tfm) { struct ocs_ecc_ctx *tctx = kpp_tfm_ctx(tfm); memzero_explicit(tctx->private_key, sizeof(*tctx->private_key)); } static unsigned int kmb_ocs_ecdh_max_size(struct crypto_kpp *tfm) { struct ocs_ecc_ctx *tctx = kpp_tfm_ctx(tfm); /* Public key is made of two coordinates, so double the digits. */ return digits_to_bytes(tctx->curve->g.ndigits) * 2; } static struct kpp_alg ocs_ecdh_p256 = { .set_secret = kmb_ocs_ecdh_set_secret, .generate_public_key = kmb_ocs_ecdh_generate_public_key, .compute_shared_secret = kmb_ocs_ecdh_compute_shared_secret, .init = kmb_ocs_ecdh_nist_p256_init_tfm, .exit = kmb_ocs_ecdh_exit_tfm, .max_size = kmb_ocs_ecdh_max_size, .base = { .cra_name = "ecdh-nist-p256", .cra_driver_name = "ecdh-nist-p256-keembay-ocs", .cra_priority = KMB_OCS_ECC_PRIORITY, .cra_module = THIS_MODULE, .cra_ctxsize = sizeof(struct ocs_ecc_ctx), }, }; static struct kpp_alg ocs_ecdh_p384 = { .set_secret = kmb_ocs_ecdh_set_secret, .generate_public_key = kmb_ocs_ecdh_generate_public_key, .compute_shared_secret = kmb_ocs_ecdh_compute_shared_secret, .init = kmb_ocs_ecdh_nist_p384_init_tfm, .exit = kmb_ocs_ecdh_exit_tfm, .max_size = kmb_ocs_ecdh_max_size, .base = { .cra_name = "ecdh-nist-p384", .cra_driver_name = "ecdh-nist-p384-keembay-ocs", .cra_priority = KMB_OCS_ECC_PRIORITY, .cra_module = THIS_MODULE, .cra_ctxsize = sizeof(struct ocs_ecc_ctx), }, }; static irqreturn_t ocs_ecc_irq_handler(int irq, void *dev_id) { struct ocs_ecc_dev *ecc_dev = dev_id; u32 status; /* * Read the status register and write it back to clear the * DONE_INT_STATUS bit. */ status = ioread32(ecc_dev->base_reg + HW_OFFS_OCS_ECC_ISR); iowrite32(status, ecc_dev->base_reg + HW_OFFS_OCS_ECC_ISR); if (!(status & HW_OCS_ECC_ISR_INT_STATUS_DONE)) return IRQ_NONE; complete(&ecc_dev->irq_done); return IRQ_HANDLED; } static int kmb_ocs_ecc_probe(struct platform_device *pdev) { struct device *dev = &pdev->dev; struct ocs_ecc_dev *ecc_dev; int rc; ecc_dev = devm_kzalloc(dev, sizeof(*ecc_dev), GFP_KERNEL); if (!ecc_dev) return -ENOMEM; ecc_dev->dev = dev; platform_set_drvdata(pdev, ecc_dev); INIT_LIST_HEAD(&ecc_dev->list); init_completion(&ecc_dev->irq_done); /* Get base register address. */ ecc_dev->base_reg = devm_platform_ioremap_resource(pdev, 0); if (IS_ERR(ecc_dev->base_reg)) { dev_err(dev, "Failed to get base address\n"); rc = PTR_ERR(ecc_dev->base_reg); goto list_del; } /* Get and request IRQ */ ecc_dev->irq = platform_get_irq(pdev, 0); if (ecc_dev->irq < 0) { rc = ecc_dev->irq; goto list_del; } rc = devm_request_threaded_irq(dev, ecc_dev->irq, ocs_ecc_irq_handler, NULL, 0, "keembay-ocs-ecc", ecc_dev); if (rc < 0) { dev_err(dev, "Could not request IRQ\n"); goto list_del; } /* Add device to the list of OCS ECC devices. */ spin_lock(&ocs_ecc.lock); list_add_tail(&ecc_dev->list, &ocs_ecc.dev_list); spin_unlock(&ocs_ecc.lock); /* Initialize crypto engine. */ ecc_dev->engine = crypto_engine_alloc_init(dev, 1); if (!ecc_dev->engine) { dev_err(dev, "Could not allocate crypto engine\n"); rc = -ENOMEM; goto list_del; } rc = crypto_engine_start(ecc_dev->engine); if (rc) { dev_err(dev, "Could not start crypto engine\n"); goto cleanup; } /* Register the KPP algo. */ rc = crypto_register_kpp(&ocs_ecdh_p256); if (rc) { dev_err(dev, "Could not register OCS algorithms with Crypto API\n"); goto cleanup; } rc = crypto_register_kpp(&ocs_ecdh_p384); if (rc) { dev_err(dev, "Could not register OCS algorithms with Crypto API\n"); goto ocs_ecdh_p384_error; } return 0; ocs_ecdh_p384_error: crypto_unregister_kpp(&ocs_ecdh_p256); cleanup: crypto_engine_exit(ecc_dev->engine); list_del: spin_lock(&ocs_ecc.lock); list_del(&ecc_dev->list); spin_unlock(&ocs_ecc.lock); return rc; } static int kmb_ocs_ecc_remove(struct platform_device *pdev) { struct ocs_ecc_dev *ecc_dev; ecc_dev = platform_get_drvdata(pdev); crypto_unregister_kpp(&ocs_ecdh_p384); crypto_unregister_kpp(&ocs_ecdh_p256); spin_lock(&ocs_ecc.lock); list_del(&ecc_dev->list); spin_unlock(&ocs_ecc.lock); crypto_engine_exit(ecc_dev->engine); return 0; } /* Device tree driver match. */ static const struct of_device_id kmb_ocs_ecc_of_match[] = { { .compatible = "intel,keembay-ocs-ecc", }, {} }; /* The OCS driver is a platform device. */ static struct platform_driver kmb_ocs_ecc_driver = { .probe = kmb_ocs_ecc_probe, .remove = kmb_ocs_ecc_remove, .driver = { .name = DRV_NAME, .of_match_table = kmb_ocs_ecc_of_match, }, }; module_platform_driver(kmb_ocs_ecc_driver); MODULE_LICENSE("GPL"); MODULE_DESCRIPTION("Intel Keem Bay OCS ECC Driver"); MODULE_ALIAS_CRYPTO("ecdh-nist-p256"); MODULE_ALIAS_CRYPTO("ecdh-nist-p384"); MODULE_ALIAS_CRYPTO("ecdh-nist-p256-keembay-ocs"); MODULE_ALIAS_CRYPTO("ecdh-nist-p384-keembay-ocs");
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