6 files changed, 581 insertions, 0 deletions

diff --git a/arch/x86/crypto/Makefile b/arch/x86/crypto/Makefile
index 2831685adf6f..b9847152acd8 100644
--- a/arch/x86/crypto/Makefile
+++ b/arch/x86/crypto/Makefile
@@ -69,6 +69,9 @@ libblake2s-x86_64-y := blake2s-core.o blake2s-glue.o
 obj-$(CONFIG_CRYPTO_GHASH_CLMUL_NI_INTEL) += ghash-clmulni-intel.o
 ghash-clmulni-intel-y := ghash-clmulni-intel_asm.o ghash-clmulni-intel_glue.o
 
+obj-$(CONFIG_CRYPTO_POLYVAL_CLMUL_NI) += polyval-clmulni.o
+polyval-clmulni-y := polyval-clmulni_asm.o polyval-clmulni_glue.o
+
 obj-$(CONFIG_CRYPTO_CRC32C_INTEL) += crc32c-intel.o
 crc32c-intel-y := crc32c-intel_glue.o
 crc32c-intel-$(CONFIG_64BIT) += crc32c-pcl-intel-asm_64.o
diff --git a/arch/x86/crypto/polyval-clmulni_asm.S b/arch/x86/crypto/polyval-clmulni_asm.S
new file mode 100644
index 000000000000..a6ebe4e7dd2b
--- /dev/null
+++ b/arch/x86/crypto/polyval-clmulni_asm.S
@@ -0,0 +1,321 @@
+/* SPDX-License-Identifier: GPL-2.0 */
+/*
+ * Copyright 2021 Google LLC
+ */
+/*
+ * This is an efficient implementation of POLYVAL using intel PCLMULQDQ-NI
+ * instructions. It works on 8 blocks at a time, by precomputing the first 8
+ * keys powers h^8, ..., h^1 in the POLYVAL finite field. This precomputation
+ * allows us to split finite field multiplication into two steps.
+ *
+ * In the first step, we consider h^i, m_i as normal polynomials of degree less
+ * than 128. We then compute p(x) = h^8m_0 + ... + h^1m_7 where multiplication
+ * is simply polynomial multiplication.
+ *
+ * In the second step, we compute the reduction of p(x) modulo the finite field
+ * modulus g(x) = x^128 + x^127 + x^126 + x^121 + 1.
+ *
+ * This two step process is equivalent to computing h^8m_0 + ... + h^1m_7 where
+ * multiplication is finite field multiplication. The advantage is that the
+ * two-step process  only requires 1 finite field reduction for every 8
+ * polynomial multiplications. Further parallelism is gained by interleaving the
+ * multiplications and polynomial reductions.
+ */
+
+#include <linux/linkage.h>
+#include <asm/frame.h>
+
+#define STRIDE_BLOCKS 8
+
+#define GSTAR %xmm7
+#define PL %xmm8
+#define PH %xmm9
+#define TMP_XMM %xmm11
+#define LO %xmm12
+#define HI %xmm13
+#define MI %xmm14
+#define SUM %xmm15
+
+#define KEY_POWERS %rdi
+#define MSG %rsi
+#define BLOCKS_LEFT %rdx
+#define ACCUMULATOR %rcx
+#define TMP %rax
+
+.section    .rodata.cst16.gstar, "aM", @progbits, 16
+.align 16
+
+.Lgstar:
+	.quad 0xc200000000000000, 0xc200000000000000
+
+.text
+
+/*
+ * Performs schoolbook1_iteration on two lists of 128-bit polynomials of length
+ * count pointed to by MSG and KEY_POWERS.
+ */
+.macro schoolbook1 count
+	.set i, 0
+	.rept (\count)
+		schoolbook1_iteration i 0
+		.set i, (i +1)
+	.endr
+.endm
+
+/*
+ * Computes the product of two 128-bit polynomials at the memory locations
+ * specified by (MSG + 16*i) and (KEY_POWERS + 16*i) and XORs the components of
+ * the 256-bit product into LO, MI, HI.
+ *
+ * Given:
+ *   X = [X_1 : X_0]
+ *   Y = [Y_1 : Y_0]
+ *
+ * We compute:
+ *   LO += X_0 * Y_0
+ *   MI += X_0 * Y_1 + X_1 * Y_0
+ *   HI += X_1 * Y_1
+ *
+ * Later, the 256-bit result can be extracted as:
+ *   [HI_1 : HI_0 + MI_1 : LO_1 + MI_0 : LO_0]
+ * This step is done when computing the polynomial reduction for efficiency
+ * reasons.
+ *
+ * If xor_sum == 1, then also XOR the value of SUM into m_0.  This avoids an
+ * extra multiplication of SUM and h^8.
+ */
+.macro schoolbook1_iteration i xor_sum
+	movups (16*\i)(MSG), %xmm0
+	.if (\i == 0 && \xor_sum == 1)
+		pxor SUM, %xmm0
+	.endif
+	vpclmulqdq $0x01, (16*\i)(KEY_POWERS), %xmm0, %xmm2
+	vpclmulqdq $0x00, (16*\i)(KEY_POWERS), %xmm0, %xmm1
+	vpclmulqdq $0x10, (16*\i)(KEY_POWERS), %xmm0, %xmm3
+	vpclmulqdq $0x11, (16*\i)(KEY_POWERS), %xmm0, %xmm4
+	vpxor %xmm2, MI, MI
+	vpxor %xmm1, LO, LO
+	vpxor %xmm4, HI, HI
+	vpxor %xmm3, MI, MI
+.endm
+
+/*
+ * Performs the same computation as schoolbook1_iteration, except we expect the
+ * arguments to already be loaded into xmm0 and xmm1 and we set the result
+ * registers LO, MI, and HI directly rather than XOR'ing into them.
+ */
+.macro schoolbook1_noload
+	vpclmulqdq $0x01, %xmm0, %xmm1, MI
+	vpclmulqdq $0x10, %xmm0, %xmm1, %xmm2
+	vpclmulqdq $0x00, %xmm0, %xmm1, LO
+	vpclmulqdq $0x11, %xmm0, %xmm1, HI
+	vpxor %xmm2, MI, MI
+.endm
+
+/*
+ * Computes the 256-bit polynomial represented by LO, HI, MI. Stores
+ * the result in PL, PH.
+ *   [PH : PL] = [HI_1 : HI_0 + MI_1 : LO_1 + MI_0 : LO_0]
+ */
+.macro schoolbook2
+	vpslldq $8, MI, PL
+	vpsrldq $8, MI, PH
+	pxor LO, PL
+	pxor HI, PH
+.endm
+
+/*
+ * Computes the 128-bit reduction of PH : PL. Stores the result in dest.
+ *
+ * This macro computes p(x) mod g(x) where p(x) is in montgomery form and g(x) =
+ * x^128 + x^127 + x^126 + x^121 + 1.
+ *
+ * We have a 256-bit polynomial PH : PL = P_3 : P_2 : P_1 : P_0 that is the
+ * product of two 128-bit polynomials in Montgomery form.  We need to reduce it
+ * mod g(x).  Also, since polynomials in Montgomery form have an "extra" factor
+ * of x^128, this product has two extra factors of x^128.  To get it back into
+ * Montgomery form, we need to remove one of these factors by dividing by x^128.
+ *
+ * To accomplish both of these goals, we add multiples of g(x) that cancel out
+ * the low 128 bits P_1 : P_0, leaving just the high 128 bits. Since the low
+ * bits are zero, the polynomial division by x^128 can be done by right shifting.
+ *
+ * Since the only nonzero term in the low 64 bits of g(x) is the constant term,
+ * the multiple of g(x) needed to cancel out P_0 is P_0 * g(x).  The CPU can
+ * only do 64x64 bit multiplications, so split P_0 * g(x) into x^128 * P_0 +
+ * x^64 * g*(x) * P_0 + P_0, where g*(x) is bits 64-127 of g(x).  Adding this to
+ * the original polynomial gives P_3 : P_2 + P_0 + T_1 : P_1 + T_0 : 0, where T
+ * = T_1 : T_0 = g*(x) * P_0.  Thus, bits 0-63 got "folded" into bits 64-191.
+ *
+ * Repeating this same process on the next 64 bits "folds" bits 64-127 into bits
+ * 128-255, giving the answer in bits 128-255. This time, we need to cancel P_1
+ * + T_0 in bits 64-127. The multiple of g(x) required is (P_1 + T_0) * g(x) *
+ * x^64. Adding this to our previous computation gives P_3 + P_1 + T_0 + V_1 :
+ * P_2 + P_0 + T_1 + V_0 : 0 : 0, where V = V_1 : V_0 = g*(x) * (P_1 + T_0).
+ *
+ * So our final computation is:
+ *   T = T_1 : T_0 = g*(x) * P_0
+ *   V = V_1 : V_0 = g*(x) * (P_1 + T_0)
+ *   p(x) / x^{128} mod g(x) = P_3 + P_1 + T_0 + V_1 : P_2 + P_0 + T_1 + V_0
+ *
+ * The implementation below saves a XOR instruction by computing P_1 + T_0 : P_0
+ * + T_1 and XORing into dest, rather than separately XORing P_1 : P_0 and T_0 :
+ * T_1 into dest.  This allows us to reuse P_1 + T_0 when computing V.
+ */
+.macro montgomery_reduction dest
+	vpclmulqdq $0x00, PL, GSTAR, TMP_XMM	# TMP_XMM = T_1 : T_0 = P_0 * g*(x)
+	pshufd $0b01001110, TMP_XMM, TMP_XMM	# TMP_XMM = T_0 : T_1
+	pxor PL, TMP_XMM			# TMP_XMM = P_1 + T_0 : P_0 + T_1
+	pxor TMP_XMM, PH			# PH = P_3 + P_1 + T_0 : P_2 + P_0 + T_1
+	pclmulqdq $0x11, GSTAR, TMP_XMM		# TMP_XMM = V_1 : V_0 = V = [(P_1 + T_0) * g*(x)]
+	vpxor TMP_XMM, PH, \dest
+.endm
+
+/*
+ * Compute schoolbook multiplication for 8 blocks
+ * m_0h^8 + ... + m_7h^1
+ *
+ * If reduce is set, also computes the montgomery reduction of the
+ * previous full_stride call and XORs with the first message block.
+ * (m_0 + REDUCE(PL, PH))h^8 + ... + m_7h^1.
+ * I.e., the first multiplication uses m_0 + REDUCE(PL, PH) instead of m_0.
+ */
+.macro full_stride reduce
+	pxor LO, LO
+	pxor HI, HI
+	pxor MI, MI
+
+	schoolbook1_iteration 7 0
+	.if \reduce
+		vpclmulqdq $0x00, PL, GSTAR, TMP_XMM
+	.endif
+
+	schoolbook1_iteration 6 0
+	.if \reduce
+		pshufd $0b01001110, TMP_XMM, TMP_XMM
+	.endif
+
+	schoolbook1_iteration 5 0
+	.if \reduce
+		pxor PL, TMP_XMM
+	.endif
+
+	schoolbook1_iteration 4 0
+	.if \reduce
+		pxor TMP_XMM, PH
+	.endif
+
+	schoolbook1_iteration 3 0
+	.if \reduce
+		pclmulqdq $0x11, GSTAR, TMP_XMM
+	.endif
+
+	schoolbook1_iteration 2 0
+	.if \reduce
+		vpxor TMP_XMM, PH, SUM
+	.endif
+
+	schoolbook1_iteration 1 0
+
+	schoolbook1_iteration 0 1
+
+	addq $(8*16), MSG
+	schoolbook2
+.endm
+
+/*
+ * Process BLOCKS_LEFT blocks, where 0 < BLOCKS_LEFT < STRIDE_BLOCKS
+ */
+.macro partial_stride
+	mov BLOCKS_LEFT, TMP
+	shlq $4, TMP
+	addq $(16*STRIDE_BLOCKS), KEY_POWERS
+	subq TMP, KEY_POWERS
+
+	movups (MSG), %xmm0
+	pxor SUM, %xmm0
+	movaps (KEY_POWERS), %xmm1
+	schoolbook1_noload
+	dec BLOCKS_LEFT
+	addq $16, MSG
+	addq $16, KEY_POWERS
+
+	test $4, BLOCKS_LEFT
+	jz .Lpartial4BlocksDone
+	schoolbook1 4
+	addq $(4*16), MSG
+	addq $(4*16), KEY_POWERS
+.Lpartial4BlocksDone:
+	test $2, BLOCKS_LEFT
+	jz .Lpartial2BlocksDone
+	schoolbook1 2
+	addq $(2*16), MSG
+	addq $(2*16), KEY_POWERS
+.Lpartial2BlocksDone:
+	test $1, BLOCKS_LEFT
+	jz .LpartialDone
+	schoolbook1 1
+.LpartialDone:
+	schoolbook2
+	montgomery_reduction SUM
+.endm
+
+/*
+ * Perform montgomery multiplication in GF(2^128) and store result in op1.
+ *
+ * Computes op1*op2*x^{-128} mod x^128 + x^127 + x^126 + x^121 + 1
+ * If op1, op2 are in montgomery form, this computes the montgomery
+ * form of op1*op2.
+ *
+ * void clmul_polyval_mul(u8 *op1, const u8 *op2);
+ */
+SYM_FUNC_START(clmul_polyval_mul)
+	FRAME_BEGIN
+	vmovdqa .Lgstar(%rip), GSTAR
+	movups (%rdi), %xmm0
+	movups (%rsi), %xmm1
+	schoolbook1_noload
+	schoolbook2
+	montgomery_reduction SUM
+	movups SUM, (%rdi)
+	FRAME_END
+	RET
+SYM_FUNC_END(clmul_polyval_mul)
+
+/*
+ * Perform polynomial evaluation as specified by POLYVAL.  This computes:
+ *	h^n * accumulator + h^n * m_0 + ... + h^1 * m_{n-1}
+ * where n=nblocks, h is the hash key, and m_i are the message blocks.
+ *
+ * rdi - pointer to precomputed key powers h^8 ... h^1
+ * rsi - pointer to message blocks
+ * rdx - number of blocks to hash
+ * rcx - pointer to the accumulator
+ *
+ * void clmul_polyval_update(const struct polyval_tfm_ctx *keys,
+ *	const u8 *in, size_t nblocks, u8 *accumulator);
+ */
+SYM_FUNC_START(clmul_polyval_update)
+	FRAME_BEGIN
+	vmovdqa .Lgstar(%rip), GSTAR
+	movups (ACCUMULATOR), SUM
+	subq $STRIDE_BLOCKS, BLOCKS_LEFT
+	js .LstrideLoopExit
+	full_stride 0
+	subq $STRIDE_BLOCKS, BLOCKS_LEFT
+	js .LstrideLoopExitReduce
+.LstrideLoop:
+	full_stride 1
+	subq $STRIDE_BLOCKS, BLOCKS_LEFT
+	jns .LstrideLoop
+.LstrideLoopExitReduce:
+	montgomery_reduction SUM
+.LstrideLoopExit:
+	add $STRIDE_BLOCKS, BLOCKS_LEFT
+	jz .LskipPartial
+	partial_stride
+.LskipPartial:
+	movups SUM, (ACCUMULATOR)
+	FRAME_END
+	RET
+SYM_FUNC_END(clmul_polyval_update)
diff --git a/arch/x86/crypto/polyval-clmulni_glue.c b/arch/x86/crypto/polyval-clmulni_glue.c
new file mode 100644
index 000000000000..b7664d018851
--- /dev/null
+++ b/arch/x86/crypto/polyval-clmulni_glue.c
@@ -0,0 +1,203 @@
+// SPDX-License-Identifier: GPL-2.0-only
+/*
+ * Glue code for POLYVAL using PCMULQDQ-NI
+ *
+ * Copyright (c) 2007 Nokia Siemens Networks - Mikko Herranen <mh1@iki.fi>
+ * Copyright (c) 2009 Intel Corp.
+ *   Author: Huang Ying <ying.huang@intel.com>
+ * Copyright 2021 Google LLC
+ */
+
+/*
+ * Glue code based on ghash-clmulni-intel_glue.c.
+ *
+ * This implementation of POLYVAL uses montgomery multiplication
+ * accelerated by PCLMULQDQ-NI to implement the finite field
+ * operations.
+ */
+
+#include <crypto/algapi.h>
+#include <crypto/internal/hash.h>
+#include <crypto/internal/simd.h>
+#include <crypto/polyval.h>
+#include <linux/crypto.h>
+#include <linux/init.h>
+#include <linux/kernel.h>
+#include <linux/module.h>
+#include <asm/cpu_device_id.h>
+#include <asm/simd.h>
+
+#define NUM_KEY_POWERS	8
+
+struct polyval_tfm_ctx {
+	/*
+	 * These powers must be in the order h^8, ..., h^1.
+	 */
+	u8 key_powers[NUM_KEY_POWERS][POLYVAL_BLOCK_SIZE];
+};
+
+struct polyval_desc_ctx {
+	u8 buffer[POLYVAL_BLOCK_SIZE];
+	u32 bytes;
+};
+
+asmlinkage void clmul_polyval_update(const struct polyval_tfm_ctx *keys,
+	const u8 *in, size_t nblocks, u8 *accumulator);
+asmlinkage void clmul_polyval_mul(u8 *op1, const u8 *op2);
+
+static void internal_polyval_update(const struct polyval_tfm_ctx *keys,
+	const u8 *in, size_t nblocks, u8 *accumulator)
+{
+	if (likely(crypto_simd_usable())) {
+		kernel_fpu_begin();
+		clmul_polyval_update(keys, in, nblocks, accumulator);
+		kernel_fpu_end();
+	} else {
+		polyval_update_non4k(keys->key_powers[NUM_KEY_POWERS-1], in,
+			nblocks, accumulator);
+	}
+}
+
+static void internal_polyval_mul(u8 *op1, const u8 *op2)
+{
+	if (likely(crypto_simd_usable())) {
+		kernel_fpu_begin();
+		clmul_polyval_mul(op1, op2);
+		kernel_fpu_end();
+	} else {
+		polyval_mul_non4k(op1, op2);
+	}
+}
+
+static int polyval_x86_setkey(struct crypto_shash *tfm,
+			const u8 *key, unsigned int keylen)
+{
+	struct polyval_tfm_ctx *tctx = crypto_shash_ctx(tfm);
+	int i;
+
+	if (keylen != POLYVAL_BLOCK_SIZE)
+		return -EINVAL;
+
+	memcpy(tctx->key_powers[NUM_KEY_POWERS-1], key, POLYVAL_BLOCK_SIZE);
+
+	for (i = NUM_KEY_POWERS-2; i >= 0; i--) {
+		memcpy(tctx->key_powers[i], key, POLYVAL_BLOCK_SIZE);
+		internal_polyval_mul(tctx->key_powers[i],
+				     tctx->key_powers[i+1]);
+	}
+
+	return 0;
+}
+
+static int polyval_x86_init(struct shash_desc *desc)
+{
+	struct polyval_desc_ctx *dctx = shash_desc_ctx(desc);
+
+	memset(dctx, 0, sizeof(*dctx));
+
+	return 0;
+}
+
+static int polyval_x86_update(struct shash_desc *desc,
+			 const u8 *src, unsigned int srclen)
+{
+	struct polyval_desc_ctx *dctx = shash_desc_ctx(desc);
+	const struct polyval_tfm_ctx *tctx = crypto_shash_ctx(desc->tfm);
+	u8 *pos;
+	unsigned int nblocks;
+	unsigned int n;
+
+	if (dctx->bytes) {
+		n = min(srclen, dctx->bytes);
+		pos = dctx->buffer + POLYVAL_BLOCK_SIZE - dctx->bytes;
+
+		dctx->bytes -= n;
+		srclen -= n;
+
+		while (n--)
+			*pos++ ^= *src++;
+
+		if (!dctx->bytes)
+			internal_polyval_mul(dctx->buffer,
+					    tctx->key_powers[NUM_KEY_POWERS-1]);
+	}
+
+	while (srclen >= POLYVAL_BLOCK_SIZE) {
+		/* Allow rescheduling every 4K bytes. */
+		nblocks = min(srclen, 4096U) / POLYVAL_BLOCK_SIZE;
+		internal_polyval_update(tctx, src, nblocks, dctx->buffer);
+		srclen -= nblocks * POLYVAL_BLOCK_SIZE;
+		src += nblocks * POLYVAL_BLOCK_SIZE;
+	}
+
+	if (srclen) {
+		dctx->bytes = POLYVAL_BLOCK_SIZE - srclen;
+		pos = dctx->buffer;
+		while (srclen--)
+			*pos++ ^= *src++;
+	}
+
+	return 0;
+}
+
+static int polyval_x86_final(struct shash_desc *desc, u8 *dst)
+{
+	struct polyval_desc_ctx *dctx = shash_desc_ctx(desc);
+	const struct polyval_tfm_ctx *tctx = crypto_shash_ctx(desc->tfm);
+
+	if (dctx->bytes) {
+		internal_polyval_mul(dctx->buffer,
+				     tctx->key_powers[NUM_KEY_POWERS-1]);
+	}
+
+	memcpy(dst, dctx->buffer, POLYVAL_BLOCK_SIZE);
+
+	return 0;
+}
+
+static struct shash_alg polyval_alg = {
+	.digestsize	= POLYVAL_DIGEST_SIZE,
+	.init		= polyval_x86_init,
+	.update		= polyval_x86_update,
+	.final		= polyval_x86_final,
+	.setkey		= polyval_x86_setkey,
+	.descsize	= sizeof(struct polyval_desc_ctx),
+	.base		= {
+		.cra_name		= "polyval",
+		.cra_driver_name	= "polyval-clmulni",
+		.cra_priority		= 200,
+		.cra_blocksize		= POLYVAL_BLOCK_SIZE,
+		.cra_ctxsize		= sizeof(struct polyval_tfm_ctx),
+		.cra_module		= THIS_MODULE,
+	},
+};
+
+__maybe_unused static const struct x86_cpu_id pcmul_cpu_id[] = {
+	X86_MATCH_FEATURE(X86_FEATURE_PCLMULQDQ, NULL),
+	{}
+};
+MODULE_DEVICE_TABLE(x86cpu, pcmul_cpu_id);
+
+static int __init polyval_clmulni_mod_init(void)
+{
+	if (!x86_match_cpu(pcmul_cpu_id))
+		return -ENODEV;
+
+	if (!boot_cpu_has(X86_FEATURE_AVX))
+		return -ENODEV;
+
+	return crypto_register_shash(&polyval_alg);
+}
+
+static void __exit polyval_clmulni_mod_exit(void)
+{
+	crypto_unregister_shash(&polyval_alg);
+}
+
+module_init(polyval_clmulni_mod_init);
+module_exit(polyval_clmulni_mod_exit);
+
+MODULE_LICENSE("GPL");
+MODULE_DESCRIPTION("POLYVAL hash function accelerated by PCLMULQDQ-NI");
+MODULE_ALIAS_CRYPTO("polyval");
+MODULE_ALIAS_CRYPTO("polyval-clmulni");
diff --git a/crypto/Kconfig b/crypto/Kconfig
index dfcc3235e918..9b654984de79 100644
--- a/crypto/Kconfig
+++ b/crypto/Kconfig
@@ -792,6 +792,15 @@ config CRYPTO_POLYVAL
 	  POLYVAL is the hash function used in HCTR2.  It is not a general-purpose
 	  cryptographic hash function.
 
+config CRYPTO_POLYVAL_CLMUL_NI
+	tristate "POLYVAL hash function (CLMUL-NI accelerated)"
+	depends on X86 && 64BIT
+	select CRYPTO_POLYVAL
+	help
+	  This is the x86_64 CLMUL-NI accelerated implementation of POLYVAL. It is
+	  used to efficiently implement HCTR2 on x86-64 processors that support
+	  carry-less multiplication instructions.
+
 config CRYPTO_POLY1305
 	tristate "Poly1305 authenticator algorithm"
 	select CRYPTO_HASH
diff --git a/crypto/polyval-generic.c b/crypto/polyval-generic.c
index bf2b03b7bfc0..16bfa6925b31 100644
--- a/crypto/polyval-generic.c
+++ b/crypto/polyval-generic.c
@@ -76,6 +76,46 @@ static void copy_and_reverse(u8 dst[POLYVAL_BLOCK_SIZE],
 	put_unaligned(swab64(b), (u64 *)&dst[0]);
 }
 
+/*
+ * Performs multiplication in the POLYVAL field using the GHASH field as a
+ * subroutine.  This function is used as a fallback for hardware accelerated
+ * implementations when simd registers are unavailable.
+ *
+ * Note: This function is not used for polyval-generic, instead we use the 4k
+ * lookup table implementation for finite field multiplication.
+ */
+void polyval_mul_non4k(u8 *op1, const u8 *op2)
+{
+	be128 a, b;
+
+	// Assume one argument is in Montgomery form and one is not.
+	copy_and_reverse((u8 *)&a, op1);
+	copy_and_reverse((u8 *)&b, op2);
+	gf128mul_x_lle(&a, &a);
+	gf128mul_lle(&a, &b);
+	copy_and_reverse(op1, (u8 *)&a);
+}
+EXPORT_SYMBOL_GPL(polyval_mul_non4k);
+
+/*
+ * Perform a POLYVAL update using non4k multiplication.  This function is used
+ * as a fallback for hardware accelerated implementations when simd registers
+ * are unavailable.
+ *
+ * Note: This function is not used for polyval-generic, instead we use the 4k
+ * lookup table implementation of finite field multiplication.
+ */
+void polyval_update_non4k(const u8 *key, const u8 *in,
+			  size_t nblocks, u8 *accumulator)
+{
+	while (nblocks--) {
+		crypto_xor(accumulator, in, POLYVAL_BLOCK_SIZE);
+		polyval_mul_non4k(accumulator, key);
+		in += POLYVAL_BLOCK_SIZE;
+	}
+}
+EXPORT_SYMBOL_GPL(polyval_update_non4k);
+
 static int polyval_setkey(struct crypto_shash *tfm,
 			  const u8 *key, unsigned int keylen)
 {
diff --git a/include/crypto/polyval.h b/include/crypto/polyval.h
index b14c38aa9166..1d630f371f77 100644
--- a/include/crypto/polyval.h
+++ b/include/crypto/polyval.h
@@ -14,4 +14,9 @@
 #define POLYVAL_BLOCK_SIZE	16
 #define POLYVAL_DIGEST_SIZE	16
 
+void polyval_mul_non4k(u8 *op1, const u8 *op2);
+
+void polyval_update_non4k(const u8 *key, const u8 *in,
+			  size_t nblocks, u8 *accumulator);
+
 #endif