/* * Copyright (C) 2012 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); you * may not use this file except in compliance with the License. You may * obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or * implied. See the License for the specific language governing * permissions and limitations under the License. */ #include <errno.h> #include <string.h> #include <stdint.h> #include <hardware/hardware.h> #include <hardware/keymaster0.h> #include <openssl/evp.h> #include <openssl/bio.h> #include <openssl/rsa.h> #include <openssl/err.h> #include <openssl/x509.h> #include <linux/ioctl.h> #include <linux/msm_ion.h> #include <sys/mman.h> #include <stdio.h> #include <stdlib.h> #include <stddef.h> #include <unistd.h> #include <dirent.h> #include <fcntl.h> #include <sys/types.h> #include <sys/stat.h> #include <dlfcn.h> #include <UniquePtr.h> #include "QSEEComAPI.h" #include "keymaster_qcom.h" // For debugging //#define LOG_NDEBUG 0 #define LOG_TAG "QCOMKeyMaster" #include <cutils/log.h> struct qcom_km_ion_info_t { int32_t ion_fd; int32_t ifd_data_fd; struct ion_handle_data ion_alloc_handle; unsigned char * ion_sbuffer; uint32_t sbuf_len; }; struct qcom_keymaster_handle { struct QSEECom_handle *qseecom; void *libhandle; int (*QSEECom_start_app)(struct QSEECom_handle ** handle, char* path, char* appname, uint32_t size); int (*QSEECom_shutdown_app)(struct QSEECom_handle **handle); int (*QSEECom_send_cmd)(struct QSEECom_handle* handle, void *cbuf, uint32_t clen, void *rbuf, uint32_t rlen); int (*QSEECom_send_modified_cmd)(struct QSEECom_handle* handle, void *cbuf, uint32_t clen, void *rbuf, uint32_t rlen, struct QSEECom_ion_fd_info *ihandle); int (*QSEECom_set_bandwidth)(struct QSEECom_handle* handle, bool high); }; typedef struct qcom_keymaster_handle qcom_keymaster_handle_t; struct EVP_PKEY_Delete { void operator()(EVP_PKEY* p) const { EVP_PKEY_free(p); } }; typedef UniquePtr<EVP_PKEY, EVP_PKEY_Delete> Unique_EVP_PKEY; struct RSA_Delete { void operator()(RSA* p) const { RSA_free(p); } }; typedef UniquePtr<RSA, RSA_Delete> Unique_RSA; typedef UniquePtr<keymaster0_device_t> Unique_keymaster_device_t; /** * Many OpenSSL APIs take ownership of an argument on success but don't free the argument * on failure. This means we need to tell our scoped pointers when we've transferred ownership, * without triggering a warning by not using the result of release(). */ #define OWNERSHIP_TRANSFERRED(obj) \ typeof (obj.release()) _dummy __attribute__((unused)) = obj.release() static int qcom_km_get_keypair_public(const keymaster0_device_t* dev, const uint8_t* keyBlob, const size_t keyBlobLength, uint8_t** x509_data, size_t* x509_data_length) { struct qcom_km_key_blob * keyblob_ptr = (struct qcom_km_key_blob *)keyBlob; if (x509_data == NULL || x509_data_length == NULL) { ALOGE("Output public key buffer == NULL"); return -1; } if (keyBlob == NULL) { ALOGE("Supplied key blob was NULL"); return -1; } // Should be large enough for keyblob data: if (keyBlobLength < (sizeof(qcom_km_key_blob_t))) { ALOGE("key blob appears to be truncated"); return -1; } if (keyblob_ptr->magic_num != KM_MAGIC_NUM) { ALOGE("Cannot read key; it was not made by this keymaster"); return -1; } if (keyblob_ptr->public_exponent_size == 0 ) { ALOGE("Key blob appears to have incorrect exponent length"); return -1; } if (keyblob_ptr->modulus_size == 0 ) { ALOGE("Key blob appears to have incorrect modulus length"); return -1; } Unique_RSA rsa(RSA_new()); if (rsa.get() == NULL) { ALOGE("Could not allocate RSA structure"); return -1; } rsa->n = BN_bin2bn(reinterpret_cast<const unsigned char*>(keyblob_ptr->modulus), keyblob_ptr->modulus_size, NULL); if (rsa->n == NULL) { ALOGE("Failed to initialize modulus"); return -1; } rsa->e = BN_bin2bn(reinterpret_cast<const unsigned char*>(&keyblob_ptr->public_exponent), keyblob_ptr->public_exponent_size, NULL); if (rsa->e == NULL) { ALOGE("Failed to initialize public exponent"); return -1; } Unique_EVP_PKEY pkey(EVP_PKEY_new()); if (pkey.get() == NULL) { ALOGE("Could not allocate EVP_PKEY structure"); return -1; } if (EVP_PKEY_assign_RSA(pkey.get(), rsa.get()) != 1) { ALOGE("Failed to assign rsa parameters \n"); return -1; } OWNERSHIP_TRANSFERRED(rsa); int len = i2d_PUBKEY(pkey.get(), NULL); if (len <= 0) { ALOGE("Len returned is < 0 len = %d", len); return -1; } UniquePtr<uint8_t> key(static_cast<uint8_t*>(malloc(len))); if (key.get() == NULL) { ALOGE("Could not allocate memory for public key data"); return -1; } unsigned char* tmp = reinterpret_cast<unsigned char*>(key.get()); if (i2d_PUBKEY(pkey.get(), &tmp) != len) { ALOGE("Len 2 returned is < 0 len = %d", len); return -1; } *x509_data_length = len; *x509_data = key.release(); return 0; } static int32_t qcom_km_ION_memalloc(struct qcom_km_ion_info_t *handle, uint32_t size) { int32_t ret = 0; int32_t iret = 0; int32_t fd = 0; unsigned char *v_addr; struct ion_allocation_data ion_alloc_data; int32_t ion_fd; int32_t rc; struct ion_fd_data ifd_data; struct ion_handle_data handle_data; /* open ION device for memory management * O_DSYNC -> uncached memory */ if(handle == NULL){ ALOGE("Error:: null handle received"); return -1; } ion_fd = open("/dev/ion", O_RDONLY | O_DSYNC); if (ion_fd < 0) { ALOGE("Error::Cannot open ION device"); return -1; } handle->ion_sbuffer = NULL; handle->ifd_data_fd = 0; /* Size of allocation */ ion_alloc_data.len = (size + 4095) & (~4095); /* 4K aligned */ ion_alloc_data.align = 4096; /* memory is allocated from EBI heap */ ion_alloc_data.ION_HEAP_MASK = ION_HEAP(ION_QSECOM_HEAP_ID); /* Set the memory to be uncached */ ion_alloc_data.flags = 0; /* IOCTL call to ION for memory request */ rc = ioctl(ion_fd, ION_IOC_ALLOC, &ion_alloc_data); if (rc) { ret = -1; goto alloc_fail; } if (ion_alloc_data.handle != NULL) { ifd_data.handle = ion_alloc_data.handle; } else { ret = -1; goto alloc_fail; } /* Call MAP ioctl to retrieve the ifd_data.fd file descriptor */ rc = ioctl(ion_fd, ION_IOC_MAP, &ifd_data); if (rc) { ret = -1; goto ioctl_fail; } /* Make the ion mmap call */ v_addr = (unsigned char *)mmap(NULL, ion_alloc_data.len, PROT_READ | PROT_WRITE, MAP_SHARED, ifd_data.fd, 0); if (v_addr == MAP_FAILED) { ALOGE("Error::ION MMAP failed"); ret = -1; goto map_fail; } handle->ion_fd = ion_fd; handle->ifd_data_fd = ifd_data.fd; handle->ion_sbuffer = v_addr; handle->ion_alloc_handle.handle = ion_alloc_data.handle; handle->sbuf_len = size; return ret; map_fail: if (handle->ion_sbuffer != NULL) { iret = munmap(handle->ion_sbuffer, ion_alloc_data.len); if (iret) ALOGE("Error::Failed to unmap memory for load image. ret = %d", ret); } ioctl_fail: handle_data.handle = ion_alloc_data.handle; if (handle->ifd_data_fd) close(handle->ifd_data_fd); iret = ioctl(ion_fd, ION_IOC_FREE, &handle_data); if (iret) { ALOGE("Error::ION FREE ioctl returned error = %d",iret); } alloc_fail: if (ion_fd > 0) close(ion_fd); return ret; } /** @brief: Deallocate ION memory * * */ static int32_t qcom_km_ion_dealloc(struct qcom_km_ion_info_t *handle) { struct ion_handle_data handle_data; int32_t ret = 0; /* Deallocate the memory for the listener */ ret = munmap(handle->ion_sbuffer, (handle->sbuf_len + 4095) & (~4095)); if (ret) { ALOGE("Error::Unmapping ION Buffer failed with ret = %d", ret); } handle_data.handle = handle->ion_alloc_handle.handle; close(handle->ifd_data_fd); ret = ioctl(handle->ion_fd, ION_IOC_FREE, &handle_data); if (ret) { ALOGE("Error::ION Memory FREE ioctl failed with ret = %d", ret); } close(handle->ion_fd); return ret; } static int qcom_km_generate_keypair(const keymaster0_device_t* dev, const keymaster_keypair_t key_type, const void* key_params, uint8_t** keyBlob, size_t* keyBlobLength) { if (dev->context == NULL) { ALOGE("qcom_km_generate_keypair: Context == NULL"); return -1; } if (key_type != TYPE_RSA) { ALOGE("Unsupported key type %d", key_type); return -1; } else if (key_params == NULL) { ALOGE("key_params == null"); return -1; } if (keyBlob == NULL || keyBlobLength == NULL) { ALOGE("output key blob or length == NULL"); return -1; } keymaster_rsa_keygen_params_t* rsa_params = (keymaster_rsa_keygen_params_t*) key_params; keymaster_gen_keypair_cmd_t *send_cmd = NULL; keymaster_gen_keypair_resp_t *resp = NULL; struct QSEECom_handle *handle = NULL; struct qcom_keymaster_handle *km_handle =(struct qcom_keymaster_handle *)dev->context; int ret = 0; handle = (struct QSEECom_handle *)(km_handle->qseecom); send_cmd = (keymaster_gen_keypair_cmd_t *)handle->ion_sbuffer; resp = (keymaster_gen_keypair_resp_t *)(handle->ion_sbuffer + QSEECOM_ALIGN(sizeof(keymaster_gen_keypair_cmd_t))); send_cmd->cmd_id = KEYMASTER_GENERATE_KEYPAIR; send_cmd->key_type = key_type; send_cmd->rsa_params.modulus_size = rsa_params->modulus_size; send_cmd->rsa_params.public_exponent = rsa_params->public_exponent; resp->status = KEYMASTER_FAILURE; resp->key_blob_len = sizeof(qcom_km_key_blob_t); ret = (*km_handle->QSEECom_set_bandwidth)(handle, true); if (ret < 0) { ALOGE("Generate key command failed (unable to enable clks) ret =%d", ret); return -1; } ret = (*km_handle->QSEECom_send_cmd)(handle, send_cmd, QSEECOM_ALIGN(sizeof(keymaster_gen_keypair_cmd_t)), resp, QSEECOM_ALIGN(sizeof(keymaster_gen_keypair_resp_t))); if((*km_handle->QSEECom_set_bandwidth)(handle, false)) ALOGE("Import key command: (unable to disable clks)"); if ( (ret < 0) || (resp->status < 0)) { ALOGE("Generate key command failed resp->status = %d ret =%d", resp->status, ret); return -1; } else { UniquePtr<unsigned char[]> keydata(new unsigned char[resp->key_blob_len]); if (keydata.get() == NULL) { ALOGE("could not allocate memory for key blob"); return -1; } unsigned char* p = keydata.get(); memcpy(p, (unsigned char *)(&resp->key_blob), resp->key_blob_len); *keyBlob = keydata.release(); *keyBlobLength = resp->key_blob_len; } return 0; } static int qcom_km_import_keypair(const keymaster0_device_t* dev, const uint8_t* key, const size_t key_length, uint8_t** keyBlob, size_t* keyBlobLength) { if (dev->context == NULL) { ALOGE("qcom_km_import_keypair: Context == NULL"); return -1; } if (key == NULL) { ALOGE("Input key == NULL"); return -1; } else if (keyBlob == NULL || keyBlobLength == NULL) { ALOGE("Output key blob or length == NULL"); return -1; } struct QSEECom_ion_fd_info ion_fd_info; struct qcom_km_ion_info_t ihandle; int ret = 0; ihandle.ion_fd = 0; ihandle.ion_alloc_handle.handle = NULL; if (qcom_km_ION_memalloc(&ihandle, QSEECOM_ALIGN(key_length)) < 0) { ALOGE("ION allocation failed"); return -1; } memset(&ion_fd_info, 0, sizeof(struct QSEECom_ion_fd_info)); /* Populate the send data structure */ ion_fd_info.data[0].fd = ihandle.ifd_data_fd; ion_fd_info.data[0].cmd_buf_offset = sizeof(enum keymaster_cmd_t); struct QSEECom_handle *handle = NULL; keymaster_import_keypair_cmd_t *send_cmd = NULL; keymaster_import_keypair_resp_t *resp = NULL; struct qcom_keymaster_handle *km_handle =(struct qcom_keymaster_handle *)dev->context; handle = (struct QSEECom_handle *)(km_handle->qseecom); send_cmd = (keymaster_import_keypair_cmd_t *)handle->ion_sbuffer; resp = (keymaster_import_keypair_resp_t *)(handle->ion_sbuffer + QSEECOM_ALIGN(sizeof(keymaster_import_keypair_cmd_t))); send_cmd->cmd_id = KEYMASTER_IMPORT_KEYPAIR; send_cmd->pkcs8_key = (uint32_t)ihandle.ion_sbuffer; memcpy((unsigned char *)ihandle.ion_sbuffer, key, key_length); send_cmd->pkcs8_key_len = key_length; resp->status = KEYMASTER_FAILURE; resp->key_blob_len = sizeof(qcom_km_key_blob_t); ret = (*km_handle->QSEECom_set_bandwidth)(handle, true); if (ret < 0) { ALOGE("Import key command failed (unable to enable clks) ret =%d", ret); qcom_km_ion_dealloc(&ihandle); return -1; } ret = (*km_handle->QSEECom_send_modified_cmd)(handle, send_cmd, QSEECOM_ALIGN(sizeof(*send_cmd)), resp, QSEECOM_ALIGN(sizeof(*resp)), &ion_fd_info); if((*km_handle->QSEECom_set_bandwidth)(handle, false)) ALOGE("Import key command: (unable to disable clks)"); if ( (ret < 0) || (resp->status < 0)) { ALOGE("Import key command failed resp->status = %d ret =%d", resp->status, ret); qcom_km_ion_dealloc(&ihandle); return -1; } else { UniquePtr<unsigned char[]> keydata(new unsigned char[resp->key_blob_len]); if (keydata.get() == NULL) { ALOGE("could not allocate memory for key blob"); return -1; } unsigned char* p = keydata.get(); memcpy(p, (unsigned char *)(&resp->key_blob), resp->key_blob_len); *keyBlob = keydata.release(); *keyBlobLength = resp->key_blob_len; } qcom_km_ion_dealloc(&ihandle); return 0; } static int qcom_km_sign_data(const keymaster0_device_t* dev, const void* params, const uint8_t* keyBlob, const size_t keyBlobLength, const uint8_t* data, const size_t dataLength, uint8_t** signedData, size_t* signedDataLength) { if (dev->context == NULL) { ALOGE("qcom_km_sign_data: Context == NULL"); return -1; } if (dataLength > KM_KEY_SIZE_MAX) { ALOGE("Input data to be signed is too long %d bytes", dataLength); return -1; } if (data == NULL) { ALOGE("input data to sign == NULL"); return -1; } else if (signedData == NULL || signedDataLength == NULL) { ALOGE("Output signature buffer == NULL"); return -1; } keymaster_rsa_sign_params_t* sign_params = (keymaster_rsa_sign_params_t*) params; if (sign_params->digest_type != DIGEST_NONE) { ALOGE("Cannot handle digest type %d", sign_params->digest_type); return -1; } else if (sign_params->padding_type != PADDING_NONE) { ALOGE("Cannot handle padding type %d", sign_params->padding_type); return -1; } struct QSEECom_handle *handle = NULL; keymaster_sign_data_cmd_t *send_cmd = NULL; keymaster_sign_data_resp_t *resp = NULL; struct QSEECom_ion_fd_info ion_fd_info; struct qcom_km_ion_info_t ihandle; struct qcom_keymaster_handle *km_handle =(struct qcom_keymaster_handle *)dev->context; int ret = 0; handle = (struct QSEECom_handle *)(km_handle->qseecom); ihandle.ion_fd = 0; ihandle.ion_alloc_handle.handle = NULL; if (qcom_km_ION_memalloc(&ihandle, dataLength) < 0) { ALOGE("ION allocation failed"); return -1; } memset(&ion_fd_info, 0, sizeof(struct QSEECom_ion_fd_info)); /* Populate the send data structure */ ion_fd_info.data[0].fd = ihandle.ifd_data_fd; ion_fd_info.data[0].cmd_buf_offset = sizeof(enum keymaster_cmd_t) + sizeof(qcom_km_key_blob_t) + sizeof(keymaster_rsa_sign_params_t); send_cmd = (keymaster_sign_data_cmd_t *)handle->ion_sbuffer; resp = (keymaster_sign_data_resp_t *)(handle->ion_sbuffer + QSEECOM_ALIGN(sizeof(keymaster_sign_data_cmd_t))); send_cmd->cmd_id = KEYMASTER_SIGN_DATA ; send_cmd->sign_param.digest_type = sign_params->digest_type; send_cmd->sign_param.padding_type = sign_params->padding_type; memcpy((unsigned char *)(&send_cmd->key_blob), keyBlob, keyBlobLength); memcpy((unsigned char *)ihandle.ion_sbuffer, data, dataLength); send_cmd->data = (uint32_t)ihandle.ion_sbuffer; send_cmd->dlen = dataLength; resp->sig_len = KM_KEY_SIZE_MAX; resp->status = KEYMASTER_FAILURE; ret = (*km_handle->QSEECom_set_bandwidth)(handle, true); if (ret < 0) { ALOGE("Sign data command failed (unable to enable clks) ret =%d", ret); qcom_km_ion_dealloc(&ihandle); return -1; } ret = (*km_handle->QSEECom_send_modified_cmd)(handle, send_cmd, QSEECOM_ALIGN(sizeof(*send_cmd)), resp, QSEECOM_ALIGN(sizeof(*resp)), &ion_fd_info); if((*km_handle->QSEECom_set_bandwidth)(handle, false)) ALOGE("Sign data command: (unable to disable clks)"); if ( (ret < 0) || (resp->status < 0)) { ALOGE("Sign data command failed resp->status = %d ret =%d", resp->status, ret); qcom_km_ion_dealloc(&ihandle); return -1; } else { UniquePtr<uint8_t> signedDataPtr(reinterpret_cast<uint8_t*>(malloc(resp->sig_len))); if (signedDataPtr.get() == NULL) { ALOGE("Sign data memory allocation failed"); qcom_km_ion_dealloc(&ihandle); return -1; } unsigned char* p = signedDataPtr.get(); memcpy(p, (unsigned char *)(&resp->signed_data), resp->sig_len); *signedDataLength = resp->sig_len; *signedData = signedDataPtr.release(); } qcom_km_ion_dealloc(&ihandle); return 0; } static int qcom_km_verify_data(const keymaster0_device_t* dev, const void* params, const uint8_t* keyBlob, const size_t keyBlobLength, const uint8_t* signedData, const size_t signedDataLength, const uint8_t* signature, const size_t signatureLength) { if (dev->context == NULL) { ALOGE("qcom_km_verify_data: Context == NULL"); return -1; } if (signedData == NULL || signature == NULL) { ALOGE("data or signature buffers == NULL"); return -1; } keymaster_rsa_sign_params_t* sign_params = (keymaster_rsa_sign_params_t*) params; if (sign_params->digest_type != DIGEST_NONE) { ALOGE("Cannot handle digest type %d", sign_params->digest_type); return -1; } else if (sign_params->padding_type != PADDING_NONE) { ALOGE("Cannot handle padding type %d", sign_params->padding_type); return -1; } else if (signatureLength != signedDataLength) { ALOGE("signed data length must be signature length"); return -1; } struct QSEECom_handle *handle = NULL; keymaster_verify_data_cmd_t *send_cmd = NULL; keymaster_verify_data_resp_t *resp = NULL; struct QSEECom_ion_fd_info ion_fd_info; struct qcom_km_ion_info_t ihandle; struct qcom_keymaster_handle *km_handle =(struct qcom_keymaster_handle *)dev->context; int ret = 0; handle = (struct QSEECom_handle *)(km_handle->qseecom); ihandle.ion_fd = 0; ihandle.ion_alloc_handle.handle = NULL; if (qcom_km_ION_memalloc(&ihandle, signedDataLength + signatureLength) <0) { ALOGE("ION allocation failed"); return -1; } memset(&ion_fd_info, 0, sizeof(struct QSEECom_ion_fd_info)); /* Populate the send data structure */ ion_fd_info.data[0].fd = ihandle.ifd_data_fd; ion_fd_info.data[0].cmd_buf_offset = sizeof(enum keymaster_cmd_t) + sizeof(qcom_km_key_blob_t ) + sizeof(keymaster_rsa_sign_params_t); send_cmd = (keymaster_verify_data_cmd_t *)handle->ion_sbuffer; resp = (keymaster_verify_data_resp_t *)((char *)handle->ion_sbuffer + sizeof(keymaster_verify_data_cmd_t)); send_cmd->cmd_id = KEYMASTER_VERIFY_DATA ; send_cmd->sign_param.digest_type = sign_params->digest_type; send_cmd->sign_param.padding_type = sign_params->padding_type; memcpy((unsigned char *)(&send_cmd->key_blob), keyBlob, keyBlobLength); send_cmd->signed_data = (uint32_t)ihandle.ion_sbuffer; send_cmd->signed_dlen = signedDataLength; memcpy((unsigned char *)ihandle.ion_sbuffer, signedData, signedDataLength); send_cmd->signature = signedDataLength; send_cmd->slen = signatureLength; memcpy(((unsigned char *)ihandle.ion_sbuffer + signedDataLength), signature, signatureLength); resp->status = KEYMASTER_FAILURE; ret = (*km_handle->QSEECom_set_bandwidth)(handle, true); if (ret < 0) { ALOGE("Verify data command failed (unable to enable clks) ret =%d", ret); qcom_km_ion_dealloc(&ihandle); return -1; } ret = (*km_handle->QSEECom_send_modified_cmd)(handle, send_cmd, QSEECOM_ALIGN(sizeof(*send_cmd)), resp, QSEECOM_ALIGN(sizeof(*resp)), &ion_fd_info); if((*km_handle->QSEECom_set_bandwidth)(handle, false)) ALOGE("Verify data command: (unable to disable clks)"); if ( (ret < 0) || (resp->status < 0)) { ALOGE("Verify data command failed resp->status = %d ret =%d", resp->status, ret); qcom_km_ion_dealloc(&ihandle); return -1; } qcom_km_ion_dealloc(&ihandle); return 0; } /* Close an opened OpenSSL instance */ static int qcom_km_close(hw_device_t *dev) { keymaster0_device_t* km_dev = (keymaster0_device_t *)dev; struct qcom_keymaster_handle *km_handle =(struct qcom_keymaster_handle *)km_dev->context; if (km_handle->qseecom == NULL) { ALOGE("Context == NULL"); return -1; } (*km_handle->QSEECom_shutdown_app)((struct QSEECom_handle **)&km_handle->qseecom); free(km_dev->context); free(dev); return 0; } static int qcom_km_get_lib_sym(qcom_keymaster_handle_t* km_handle) { km_handle->libhandle = dlopen("libQSEEComAPI.so", RTLD_NOW); if ( km_handle->libhandle ) { *(void **)(&km_handle->QSEECom_start_app) = dlsym(km_handle->libhandle,"QSEECom_start_app"); if (km_handle->QSEECom_start_app == NULL) { ALOGE("dlsym: Error Loading QSEECom_start_app"); dlclose(km_handle->libhandle ); km_handle->libhandle = NULL; return -1; } *(void **)(&km_handle->QSEECom_shutdown_app) = dlsym(km_handle->libhandle,"QSEECom_shutdown_app"); if (km_handle->QSEECom_shutdown_app == NULL) { ALOGE("dlsym: Error Loading QSEECom_shutdown_app"); dlclose(km_handle->libhandle ); km_handle->libhandle = NULL; return -1; } *(void **)(&km_handle->QSEECom_send_cmd) = dlsym(km_handle->libhandle,"QSEECom_send_cmd"); if (km_handle->QSEECom_send_cmd == NULL) { ALOGE("dlsym: Error Loading QSEECom_send_cmd"); dlclose(km_handle->libhandle ); km_handle->libhandle = NULL; return -1; } *(void **)(&km_handle->QSEECom_send_modified_cmd) = dlsym(km_handle->libhandle,"QSEECom_send_modified_cmd"); if (km_handle->QSEECom_send_modified_cmd == NULL) { ALOGE("dlsym: Error Loading QSEECom_send_modified_cmd"); dlclose(km_handle->libhandle ); km_handle->libhandle = NULL; return -1; } *(void **)(&km_handle->QSEECom_set_bandwidth) = dlsym(km_handle->libhandle,"QSEECom_set_bandwidth"); if (km_handle->QSEECom_set_bandwidth == NULL) { ALOGE("dlsym: Error Loading QSEECom_set_bandwidth"); dlclose(km_handle->libhandle ); km_handle->libhandle = NULL; return -1; } } else { ALOGE("failed to load qseecom library"); return -1; } return 0; } /* * Generic device handling */ static int qcom_km_open(const hw_module_t* module, const char* name, hw_device_t** device) { int ret = 0; qcom_keymaster_handle_t* km_handle; if (strcmp(name, KEYSTORE_KEYMASTER) != 0) return -EINVAL; km_handle = (qcom_keymaster_handle_t *)malloc(sizeof(qcom_keymaster_handle_t)); if (km_handle == NULL) { ALOGE("Memalloc for keymaster handle failed"); return -1; } km_handle->qseecom = NULL; km_handle->libhandle = NULL; ret = qcom_km_get_lib_sym(km_handle); if (ret) { free(km_handle); return -1; } Unique_keymaster_device_t dev(new keymaster0_device_t); if (dev.get() == NULL){ free(km_handle); return -ENOMEM; } dev->context = (void *)km_handle; ret = (*km_handle->QSEECom_start_app)((struct QSEECom_handle **)&km_handle->qseecom, "/vendor/firmware/keymaster", "keymaster", 4096*2); if (ret) { ALOGE("Loading keymaster app failed"); free(km_handle); return -1; } dev->common.tag = HARDWARE_DEVICE_TAG; dev->common.version = 1; dev->common.module = (struct hw_module_t*) module; dev->common.close = qcom_km_close; dev->flags = KEYMASTER_BLOBS_ARE_STANDALONE; dev->generate_keypair = qcom_km_generate_keypair; dev->import_keypair = qcom_km_import_keypair; dev->get_keypair_public = qcom_km_get_keypair_public; dev->delete_keypair = NULL; dev->delete_all = NULL; dev->sign_data = qcom_km_sign_data; dev->verify_data = qcom_km_verify_data; *device = reinterpret_cast<hw_device_t*>(dev.release()); return 0; } static struct hw_module_methods_t keystore_module_methods = { .open = qcom_km_open, }; struct keystore_module HAL_MODULE_INFO_SYM __attribute__ ((visibility ("default"))) = { .common = { .tag = HARDWARE_MODULE_TAG, .module_api_version = QCOM_KEYMASTER_API_VERSION, .hal_api_version = HARDWARE_HAL_API_VERSION, .id = KEYSTORE_HARDWARE_MODULE_ID, .name = "Keymaster QCOM HAL", .author = "The Android Open Source Project", .methods = &keystore_module_methods, .dso = 0, .reserved = {}, }, };