diff mbox series

[v3,07/12] qcom_scm: scm call for create, prepare and import keys

Message ID 20231122053817.3401748-8-quic_gaurkash@quicinc.com
State New
Headers show
Series Hardware wrapped key support for qcom ice and ufs | expand

Commit Message

Gaurav Kashyap (QUIC) Nov. 22, 2023, 5:38 a.m. UTC
Storage encryption has two IOCTLs for creating, importing
and preparing keys for encryption. For wrapped keys, these
IOCTLs need to interface with the secure environment, which
require these SCM calls.

generate_key: This is used to generate and return a longterm
              wrapped key. Trustzone achieves this by generating
	      a key and then wrapping it using hwkm, returning
	      a wrapped keyblob.
import_key:   The functionality is similar to generate, but here,
              a raw key is imported into hwkm and a longterm wrapped
	      keyblob is returned.
prepare_key:  The longterm wrapped key from import or generate
              is made further secure by rewrapping it with a per-boot
	      ephemeral wrapped key before installing it to the linux
	      kernel for programming to ICE.

Signed-off-by: Gaurav Kashyap <quic_gaurkash@quicinc.com>
---
 drivers/firmware/qcom/qcom_scm.c       | 205 +++++++++++++++++++++++++
 drivers/firmware/qcom/qcom_scm.h       |   3 +
 include/linux/firmware/qcom/qcom_scm.h |   5 +
 3 files changed, 213 insertions(+)

Comments

Mukesh Ojha Dec. 13, 2023, 8:11 a.m. UTC | #1
On 11/22/2023 11:08 AM, Gaurav Kashyap wrote:
> Storage encryption has two IOCTLs for creating, importing
> and preparing keys for encryption. For wrapped keys, these
> IOCTLs need to interface with the secure environment, which
> require these SCM calls.
> 
> generate_key: This is used to generate and return a longterm
>                wrapped key. Trustzone achieves this by generating
> 	      a key and then wrapping it using hwkm, returning
> 	      a wrapped keyblob.
> import_key:   The functionality is similar to generate, but here,
>                a raw key is imported into hwkm and a longterm wrapped
> 	      keyblob is returned.
> prepare_key:  The longterm wrapped key from import or generate
>                is made further secure by rewrapping it with a per-boot
> 	      ephemeral wrapped key before installing it to the linux
> 	      kernel for programming to ICE.
> 
> Signed-off-by: Gaurav Kashyap <quic_gaurkash@quicinc.com>

[..]
> ---
>   drivers/firmware/qcom/qcom_scm.c       | 205 +++++++++++++++++++++++++
>   drivers/firmware/qcom/qcom_scm.h       |   3 +
>   include/linux/firmware/qcom/qcom_scm.h |   5 +
>   3 files changed, 213 insertions(+)
> 
> diff --git a/drivers/firmware/qcom/qcom_scm.c b/drivers/firmware/qcom/qcom_scm.c
> index 6dfb913f3e33..259b3c316019 100644
> --- a/drivers/firmware/qcom/qcom_scm.c
> +++ b/drivers/firmware/qcom/qcom_scm.c
> @@ -1285,6 +1285,211 @@ int qcom_scm_derive_sw_secret(const u8 *wkey, size_t wkey_size,
>   }
>   EXPORT_SYMBOL(qcom_scm_derive_sw_secret);
>   
> +/**
> + * qcom_scm_generate_ice_key() - Generate a wrapped key for encryption.
> + * @lt_key: the wrapped key returned after key generation
> + * @lt_key_size: size of the wrapped key to be returned.
> + *
> + * Qualcomm wrapped keys need to be generated in a trusted environment.
> + * A generate key  IOCTL call is used to achieve this. These are longterm

nit: remove space after key

> + * in nature as they need to be generated and wrapped only once per
> + * requirement.
> + *
> + * This SCM calls adds support for the create key IOCTL to interface

Just starting with "Adds support... " would do.

> + * with the secure environment to generate and return a wrapped key..
> + *
> + * Return: 0 on success; -errno on failure.
> + */
> +int qcom_scm_generate_ice_key(u8 *lt_key, size_t lt_key_size)
> +{
> +	struct qcom_scm_desc desc = {
> +		.svc = QCOM_SCM_SVC_ES,
> +		.cmd =  QCOM_SCM_ES_GENERATE_ICE_KEY,
> +		.arginfo = QCOM_SCM_ARGS(2, QCOM_SCM_RW,
> +					 QCOM_SCM_VAL),

Keep this in one line.

> +		.args[1] = lt_key_size,
> +		.owner = ARM_SMCCC_OWNER_SIP,
> +	};
> +
> +	void *lt_key_buf;
> +	dma_addr_t lt_key_phys; > +	int ret;

reverse x-mas tree is the everyone looks to be following..

dma_addr_t lt_key_phys;
void *lt_key_buf;
int ret;

> +
> +	/*
> +	 * Like qcom_scm_ice_set_key(), we use dma_alloc_coherent() to properly
> +	 * get a physical address, while guaranteeing that we can zeroize the
> +	 * key material later using memzero_explicit().
> +	 *

Extra *

> +	 */
> +	lt_key_buf = dma_alloc_coherent(__scm->dev, lt_key_size, &lt_key_phys, GFP_KERNEL);
> +	if (!lt_key_buf)
> +		return -ENOMEM;
> +
> +	desc.args[0] = lt_key_phys;
> +
> +	ret = qcom_scm_call(__scm->dev, &desc, NULL);
> +	memcpy(lt_key, lt_key_buf, lt_key_size);

Do you really want to copy the key buf if the scm call fails ?

> +
> +	memzero_explicit(lt_key_buf, lt_key_size);
> +
> +	dma_free_coherent(__scm->dev, lt_key_size, lt_key_buf, lt_key_phys);
> +
> +	if (!ret)

why this is here instead of just after qcom_scm_call() ?

> +		return lt_key_size;

You said, you will return 0 on success.

> +
> +	return ret;
> +}
> +EXPORT_SYMBOL_GPL(qcom_scm_generate_ice_key);
> +
> +/**
> + * qcom_scm_prepare_ice_key() - Get per boot ephemeral wrapped key
> + * @lt_key: the longterm wrapped key
> + * @lt_key_size: size of the wrapped key
> + * @eph_key: ephemeral wrapped key to be returned
> + * @eph_key_size: size of the ephemeral wrapped key
> + *
> + * Qualcomm wrapped keys (longterm keys) are rewrapped with a per-boot
> + * ephemeral key for added protection. These are ephemeral in nature as
> + * they are valid only for that boot. A create key IOCTL is used to
> + * achieve this. These are the keys that are installed into the kernel
> + * to be then unwrapped and programmed into ICE.
> + *
> + * This SCM call adds support for the create key IOCTL to interface
> + * with the secure environment to rewrap the wrapped key with an
> + * ephemeral wrapping key.
> + *
> + * Return: 0 on success; -errno on failure.
> + */
> +int qcom_scm_prepare_ice_key(const u8 *lt_key, size_t lt_key_size,
> +			     u8 *eph_key, size_t eph_key_size)
> +{
> +	struct qcom_scm_desc desc = {
> +		.svc = QCOM_SCM_SVC_ES,
> +		.cmd =  QCOM_SCM_ES_PREPARE_ICE_KEY,
> +		.arginfo = QCOM_SCM_ARGS(4, QCOM_SCM_RO,
> +					 QCOM_SCM_VAL, QCOM_SCM_RW,
> +					 QCOM_SCM_VAL),
> +		.args[1] = lt_key_size,
> +		.args[3] = eph_key_size,
> +		.owner = ARM_SMCCC_OWNER_SIP,
> +	};
> +
> +	void *lt_key_buf, *eph_key_buf;
> +	dma_addr_t lt_key_phys, eph_key_phys;
> +	int ret;

One variable and R-XMAS is the norm..
> +
> +	/*
> +	 * Like qcom_scm_ice_set_key(), we use dma_alloc_coherent() to properly
> +	 * get a physical address, while guaranteeing that we can zeroize the
> +	 * key material later using memzero_explicit().
> +	 *

extra *

> +	 */
> +	lt_key_buf = dma_alloc_coherent(__scm->dev, lt_key_size, &lt_key_phys, GFP_KERNEL);
> +	if (!lt_key_buf)
> +		return -ENOMEM;
> +	eph_key_buf = dma_alloc_coherent(__scm->dev, eph_key_size, &eph_key_phys, GFP_KERNEL);
> +	if (!eph_key_buf) {
> +		ret = -ENOMEM;
> +		goto err_free_longterm;
> +	}
> +
> +	memcpy(lt_key_buf, lt_key, lt_key_size);
> +	desc.args[0] = lt_key_phys;
> +	desc.args[2] = eph_key_phys;
> +
> +	ret = qcom_scm_call(__scm->dev, &desc, NULL);
> +	if (!ret)
> +		memcpy(eph_key, eph_key_buf, eph_key_size);
> +
> +	memzero_explicit(eph_key_buf, eph_key_size);
> +
> +	dma_free_coherent(__scm->dev, eph_key_size, eph_key_buf, eph_key_phys);
> +
> +err_free_longterm:
> +	memzero_explicit(lt_key_buf, lt_key_size);
> +
> +	dma_free_coherent(__scm->dev, lt_key_size, lt_key_buf, lt_key_phys);
> +
> +	if (!ret)
> +		return eph_key_size;

you said, this will return 0 on success..
> +
> +	return ret;
> +}
> +EXPORT_SYMBOL_GPL(qcom_scm_prepare_ice_key);
> +
> +/**
> + * qcom_scm_import_ice_key() - Import a wrapped key for encryption
> + * @imp_key: the raw key that is imported
> + * @imp_key_size: size of the key to be imported
> + * @lt_key: the wrapped key to be returned
> + * @lt_key_size: size of the wrapped key
> + *
> + * Conceptually, this is very similar to generate, the difference being,
> + * here we want to import a raw key and return a longterm wrapped key
> + * from it. The same create key IOCTL is used to achieve this.
> + *
> + * This SCM call adds support for the create key IOCTL to interface with
> + * the secure environment to import a raw key and generate a longterm
> + * wrapped key.
> + *
> + * Return: 0 on success; -errno on failure.
> + */
> +int qcom_scm_import_ice_key(const u8 *imp_key, size_t imp_key_size,
> +			    u8 *lt_key, size_t lt_key_size)
> +{
> +	struct qcom_scm_desc desc = {
> +		.svc = QCOM_SCM_SVC_ES,
> +		.cmd =  QCOM_SCM_ES_IMPORT_ICE_KEY,
> +		.arginfo = QCOM_SCM_ARGS(4, QCOM_SCM_RO,
> +					 QCOM_SCM_VAL, QCOM_SCM_RW,
> +					 QCOM_SCM_VAL),
> +		.args[1] = imp_key_size,
> +		.args[3] = lt_key_size,
> +		.owner = ARM_SMCCC_OWNER_SIP,
> +	};
> +
> +	void *imp_key_buf, *lt_key_buf;
> +	dma_addr_t imp_key_phys, lt_key_phys;
> +	int ret;
> +	/*
> +	 * Like qcom_scm_ice_set_key(), we use dma_alloc_coherent() to properly
> +	 * get a physical address, while guaranteeing that we can zeroize the
> +	 * key material later using memzero_explicit().
> +	 *

Extra  *

> +	 */
> +	imp_key_buf = dma_alloc_coherent(__scm->dev, imp_key_size, &imp_key_phys, GFP_KERNEL);
> +	if (!imp_key_buf)
> +		return -ENOMEM;
> +	lt_key_buf = dma_alloc_coherent(__scm->dev, lt_key_size, &lt_key_phys, GFP_KERNEL);
> +	if (!lt_key_buf) {
> +		ret = -ENOMEM;
> +		goto err_free_longterm;
> +	}
> +
> +	memcpy(imp_key_buf, imp_key, imp_key_size);
> +	desc.args[0] = imp_key_phys;
> +	desc.args[2] = lt_key_phys;
> +
> +	ret = qcom_scm_call(__scm->dev, &desc, NULL);
> +	if (!ret)
> +		memcpy(lt_key, lt_key_buf, lt_key_size);
> +
> +	memzero_explicit(lt_key_buf, lt_key_size);
> +

Why there is unnecessary line gap everywhere between lines ?

> +	dma_free_coherent(__scm->dev, lt_key_size, lt_key_buf, lt_key_phys);
> +
> +err_free_longterm:
> +	memzero_explicit(imp_key_buf, imp_key_size);
> +
> +	dma_free_coherent(__scm->dev, imp_key_size, imp_key_buf, imp_key_phys);
> +
> +	if (!ret)
> +		return lt_key_size;

same as above comment on return value..

-Mukesh

> +
> +	return ret;
> +}
> +EXPORT_SYMBOL_GPL(qcom_scm_import_ice_key);
> +
>   /**
>    * qcom_scm_hdcp_available() - Check if secure environment supports HDCP.
>    *
> diff --git a/drivers/firmware/qcom/qcom_scm.h b/drivers/firmware/qcom/qcom_scm.h
> index c75456aa6ac5..d89ab5446ba5 100644
> --- a/drivers/firmware/qcom/qcom_scm.h
> +++ b/drivers/firmware/qcom/qcom_scm.h
> @@ -122,6 +122,9 @@ int scm_legacy_call(struct device *dev, const struct qcom_scm_desc *desc,
>   #define QCOM_SCM_ES_INVALIDATE_ICE_KEY	0x03
>   #define QCOM_SCM_ES_CONFIG_SET_ICE_KEY	0x04
>   #define QCOM_SCM_ES_DERIVE_SW_SECRET	0x07
> +#define QCOM_SCM_ES_GENERATE_ICE_KEY	0x08
> +#define QCOM_SCM_ES_PREPARE_ICE_KEY	0x09
> +#define QCOM_SCM_ES_IMPORT_ICE_KEY	0xA
>   
>   #define QCOM_SCM_SVC_HDCP		0x11
>   #define QCOM_SCM_HDCP_INVOKE		0x01
> diff --git a/include/linux/firmware/qcom/qcom_scm.h b/include/linux/firmware/qcom/qcom_scm.h
> index c65f2d61492d..477aeec6255e 100644
> --- a/include/linux/firmware/qcom/qcom_scm.h
> +++ b/include/linux/firmware/qcom/qcom_scm.h
> @@ -105,6 +105,11 @@ int qcom_scm_ice_set_key(u32 index, const u8 *key, u32 key_size,
>   			 enum qcom_scm_ice_cipher cipher, u32 data_unit_size);
>   int qcom_scm_derive_sw_secret(const u8 *wkey, size_t wkey_size,
>   			      u8 *sw_secret, size_t sw_secret_size);
> +int qcom_scm_generate_ice_key(u8 *lt_key, size_t lt_key_size);
> +int qcom_scm_prepare_ice_key(const u8 *lt_key, size_t lt_key_size,
> +			     u8 *eph_key, size_t eph_size);
> +int qcom_scm_import_ice_key(const u8 *imp_key, size_t imp_size,
> +			    u8 *lt_key, size_t lt_key_size);
>   
>   bool qcom_scm_hdcp_available(void);
>   int qcom_scm_hdcp_req(struct qcom_scm_hdcp_req *req, u32 req_cnt, u32 *resp);
diff mbox series

Patch

diff --git a/drivers/firmware/qcom/qcom_scm.c b/drivers/firmware/qcom/qcom_scm.c
index 6dfb913f3e33..259b3c316019 100644
--- a/drivers/firmware/qcom/qcom_scm.c
+++ b/drivers/firmware/qcom/qcom_scm.c
@@ -1285,6 +1285,211 @@  int qcom_scm_derive_sw_secret(const u8 *wkey, size_t wkey_size,
 }
 EXPORT_SYMBOL(qcom_scm_derive_sw_secret);
 
+/**
+ * qcom_scm_generate_ice_key() - Generate a wrapped key for encryption.
+ * @lt_key: the wrapped key returned after key generation
+ * @lt_key_size: size of the wrapped key to be returned.
+ *
+ * Qualcomm wrapped keys need to be generated in a trusted environment.
+ * A generate key  IOCTL call is used to achieve this. These are longterm
+ * in nature as they need to be generated and wrapped only once per
+ * requirement.
+ *
+ * This SCM calls adds support for the create key IOCTL to interface
+ * with the secure environment to generate and return a wrapped key..
+ *
+ * Return: 0 on success; -errno on failure.
+ */
+int qcom_scm_generate_ice_key(u8 *lt_key, size_t lt_key_size)
+{
+	struct qcom_scm_desc desc = {
+		.svc = QCOM_SCM_SVC_ES,
+		.cmd =  QCOM_SCM_ES_GENERATE_ICE_KEY,
+		.arginfo = QCOM_SCM_ARGS(2, QCOM_SCM_RW,
+					 QCOM_SCM_VAL),
+		.args[1] = lt_key_size,
+		.owner = ARM_SMCCC_OWNER_SIP,
+	};
+
+	void *lt_key_buf;
+	dma_addr_t lt_key_phys;
+	int ret;
+
+	/*
+	 * Like qcom_scm_ice_set_key(), we use dma_alloc_coherent() to properly
+	 * get a physical address, while guaranteeing that we can zeroize the
+	 * key material later using memzero_explicit().
+	 *
+	 */
+	lt_key_buf = dma_alloc_coherent(__scm->dev, lt_key_size, &lt_key_phys, GFP_KERNEL);
+	if (!lt_key_buf)
+		return -ENOMEM;
+
+	desc.args[0] = lt_key_phys;
+
+	ret = qcom_scm_call(__scm->dev, &desc, NULL);
+	memcpy(lt_key, lt_key_buf, lt_key_size);
+
+	memzero_explicit(lt_key_buf, lt_key_size);
+
+	dma_free_coherent(__scm->dev, lt_key_size, lt_key_buf, lt_key_phys);
+
+	if (!ret)
+		return lt_key_size;
+
+	return ret;
+}
+EXPORT_SYMBOL_GPL(qcom_scm_generate_ice_key);
+
+/**
+ * qcom_scm_prepare_ice_key() - Get per boot ephemeral wrapped key
+ * @lt_key: the longterm wrapped key
+ * @lt_key_size: size of the wrapped key
+ * @eph_key: ephemeral wrapped key to be returned
+ * @eph_key_size: size of the ephemeral wrapped key
+ *
+ * Qualcomm wrapped keys (longterm keys) are rewrapped with a per-boot
+ * ephemeral key for added protection. These are ephemeral in nature as
+ * they are valid only for that boot. A create key IOCTL is used to
+ * achieve this. These are the keys that are installed into the kernel
+ * to be then unwrapped and programmed into ICE.
+ *
+ * This SCM call adds support for the create key IOCTL to interface
+ * with the secure environment to rewrap the wrapped key with an
+ * ephemeral wrapping key.
+ *
+ * Return: 0 on success; -errno on failure.
+ */
+int qcom_scm_prepare_ice_key(const u8 *lt_key, size_t lt_key_size,
+			     u8 *eph_key, size_t eph_key_size)
+{
+	struct qcom_scm_desc desc = {
+		.svc = QCOM_SCM_SVC_ES,
+		.cmd =  QCOM_SCM_ES_PREPARE_ICE_KEY,
+		.arginfo = QCOM_SCM_ARGS(4, QCOM_SCM_RO,
+					 QCOM_SCM_VAL, QCOM_SCM_RW,
+					 QCOM_SCM_VAL),
+		.args[1] = lt_key_size,
+		.args[3] = eph_key_size,
+		.owner = ARM_SMCCC_OWNER_SIP,
+	};
+
+	void *lt_key_buf, *eph_key_buf;
+	dma_addr_t lt_key_phys, eph_key_phys;
+	int ret;
+
+	/*
+	 * Like qcom_scm_ice_set_key(), we use dma_alloc_coherent() to properly
+	 * get a physical address, while guaranteeing that we can zeroize the
+	 * key material later using memzero_explicit().
+	 *
+	 */
+	lt_key_buf = dma_alloc_coherent(__scm->dev, lt_key_size, &lt_key_phys, GFP_KERNEL);
+	if (!lt_key_buf)
+		return -ENOMEM;
+	eph_key_buf = dma_alloc_coherent(__scm->dev, eph_key_size, &eph_key_phys, GFP_KERNEL);
+	if (!eph_key_buf) {
+		ret = -ENOMEM;
+		goto err_free_longterm;
+	}
+
+	memcpy(lt_key_buf, lt_key, lt_key_size);
+	desc.args[0] = lt_key_phys;
+	desc.args[2] = eph_key_phys;
+
+	ret = qcom_scm_call(__scm->dev, &desc, NULL);
+	if (!ret)
+		memcpy(eph_key, eph_key_buf, eph_key_size);
+
+	memzero_explicit(eph_key_buf, eph_key_size);
+
+	dma_free_coherent(__scm->dev, eph_key_size, eph_key_buf, eph_key_phys);
+
+err_free_longterm:
+	memzero_explicit(lt_key_buf, lt_key_size);
+
+	dma_free_coherent(__scm->dev, lt_key_size, lt_key_buf, lt_key_phys);
+
+	if (!ret)
+		return eph_key_size;
+
+	return ret;
+}
+EXPORT_SYMBOL_GPL(qcom_scm_prepare_ice_key);
+
+/**
+ * qcom_scm_import_ice_key() - Import a wrapped key for encryption
+ * @imp_key: the raw key that is imported
+ * @imp_key_size: size of the key to be imported
+ * @lt_key: the wrapped key to be returned
+ * @lt_key_size: size of the wrapped key
+ *
+ * Conceptually, this is very similar to generate, the difference being,
+ * here we want to import a raw key and return a longterm wrapped key
+ * from it. The same create key IOCTL is used to achieve this.
+ *
+ * This SCM call adds support for the create key IOCTL to interface with
+ * the secure environment to import a raw key and generate a longterm
+ * wrapped key.
+ *
+ * Return: 0 on success; -errno on failure.
+ */
+int qcom_scm_import_ice_key(const u8 *imp_key, size_t imp_key_size,
+			    u8 *lt_key, size_t lt_key_size)
+{
+	struct qcom_scm_desc desc = {
+		.svc = QCOM_SCM_SVC_ES,
+		.cmd =  QCOM_SCM_ES_IMPORT_ICE_KEY,
+		.arginfo = QCOM_SCM_ARGS(4, QCOM_SCM_RO,
+					 QCOM_SCM_VAL, QCOM_SCM_RW,
+					 QCOM_SCM_VAL),
+		.args[1] = imp_key_size,
+		.args[3] = lt_key_size,
+		.owner = ARM_SMCCC_OWNER_SIP,
+	};
+
+	void *imp_key_buf, *lt_key_buf;
+	dma_addr_t imp_key_phys, lt_key_phys;
+	int ret;
+	/*
+	 * Like qcom_scm_ice_set_key(), we use dma_alloc_coherent() to properly
+	 * get a physical address, while guaranteeing that we can zeroize the
+	 * key material later using memzero_explicit().
+	 *
+	 */
+	imp_key_buf = dma_alloc_coherent(__scm->dev, imp_key_size, &imp_key_phys, GFP_KERNEL);
+	if (!imp_key_buf)
+		return -ENOMEM;
+	lt_key_buf = dma_alloc_coherent(__scm->dev, lt_key_size, &lt_key_phys, GFP_KERNEL);
+	if (!lt_key_buf) {
+		ret = -ENOMEM;
+		goto err_free_longterm;
+	}
+
+	memcpy(imp_key_buf, imp_key, imp_key_size);
+	desc.args[0] = imp_key_phys;
+	desc.args[2] = lt_key_phys;
+
+	ret = qcom_scm_call(__scm->dev, &desc, NULL);
+	if (!ret)
+		memcpy(lt_key, lt_key_buf, lt_key_size);
+
+	memzero_explicit(lt_key_buf, lt_key_size);
+
+	dma_free_coherent(__scm->dev, lt_key_size, lt_key_buf, lt_key_phys);
+
+err_free_longterm:
+	memzero_explicit(imp_key_buf, imp_key_size);
+
+	dma_free_coherent(__scm->dev, imp_key_size, imp_key_buf, imp_key_phys);
+
+	if (!ret)
+		return lt_key_size;
+
+	return ret;
+}
+EXPORT_SYMBOL_GPL(qcom_scm_import_ice_key);
+
 /**
  * qcom_scm_hdcp_available() - Check if secure environment supports HDCP.
  *
diff --git a/drivers/firmware/qcom/qcom_scm.h b/drivers/firmware/qcom/qcom_scm.h
index c75456aa6ac5..d89ab5446ba5 100644
--- a/drivers/firmware/qcom/qcom_scm.h
+++ b/drivers/firmware/qcom/qcom_scm.h
@@ -122,6 +122,9 @@  int scm_legacy_call(struct device *dev, const struct qcom_scm_desc *desc,
 #define QCOM_SCM_ES_INVALIDATE_ICE_KEY	0x03
 #define QCOM_SCM_ES_CONFIG_SET_ICE_KEY	0x04
 #define QCOM_SCM_ES_DERIVE_SW_SECRET	0x07
+#define QCOM_SCM_ES_GENERATE_ICE_KEY	0x08
+#define QCOM_SCM_ES_PREPARE_ICE_KEY	0x09
+#define QCOM_SCM_ES_IMPORT_ICE_KEY	0xA
 
 #define QCOM_SCM_SVC_HDCP		0x11
 #define QCOM_SCM_HDCP_INVOKE		0x01
diff --git a/include/linux/firmware/qcom/qcom_scm.h b/include/linux/firmware/qcom/qcom_scm.h
index c65f2d61492d..477aeec6255e 100644
--- a/include/linux/firmware/qcom/qcom_scm.h
+++ b/include/linux/firmware/qcom/qcom_scm.h
@@ -105,6 +105,11 @@  int qcom_scm_ice_set_key(u32 index, const u8 *key, u32 key_size,
 			 enum qcom_scm_ice_cipher cipher, u32 data_unit_size);
 int qcom_scm_derive_sw_secret(const u8 *wkey, size_t wkey_size,
 			      u8 *sw_secret, size_t sw_secret_size);
+int qcom_scm_generate_ice_key(u8 *lt_key, size_t lt_key_size);
+int qcom_scm_prepare_ice_key(const u8 *lt_key, size_t lt_key_size,
+			     u8 *eph_key, size_t eph_size);
+int qcom_scm_import_ice_key(const u8 *imp_key, size_t imp_size,
+			    u8 *lt_key, size_t lt_key_size);
 
 bool qcom_scm_hdcp_available(void);
 int qcom_scm_hdcp_req(struct qcom_scm_hdcp_req *req, u32 req_cnt, u32 *resp);